System and method of paging in next generation wireless communication system

ABSTRACT

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. An apparatus and method are provided for transmitting/receiving a paging message in a next generation communication system.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.15/629,620, filed Jun. 21, 2017, which claims priority to IndianProvisional Application No. 201641021194, filed Jun. 21, 2016, theentire disclosures of which are incorporated herein by reference.

BACKGROUND 1. Field

The present disclosure relates generally to a paging procedure, and moreparticularly, to a paging procedure in next generation communicationsystem.

2. Description of Related Art

In the recent years several broadband wireless technologies have beendeveloped to meet the growing number of broadband subscribers and toprovide more and better applications and services. The 3^(rd) generationpartnership project 2 (3GPP2) developed code division multiple access2000 (CDMA 2000), 1× evolution data optimized (1×EVDO) and ultra mobilebroadband (UMB) systems. The 3^(rd) generation partnership project(3GPP) developed wideband code division multiple access (WCDMA), highspeed packet access (HSPA) and long term evolution (LTE) systems. TheInstitute of Electrical and Electronics Engineers developed mobileworldwide interoperability for microwave access (WiMAX) systems. As moreand more people become users of mobile communication systems and moreand more services are provided over these systems, there is anincreasing need mobile communication system with large capacity, highthroughput, lower latency and better reliability.

To meet the demand for wireless data traffic having increased sincedeployment of 4G communication systems, efforts have been made todevelop an improved 5G or pre-5G communication system. Therefore, the 5Gor pre-5G communication system is also called a “Beyond 4G Network” or a“Post LTE System.” The 5G communication system is considered to beimplemented in higher frequency (mmWave) bands, e.g., 60 GHz bands, soas to accomplish higher data rates. To decrease propagation loss of theradio waves and increase the transmission distance, the beamforming,massive multiple-input multiple-output (MIMO), Full Dimensional MIMO(FD-MIMO), array antenna, an analog beam forming, large scale antennatechniques are discussed in 5G communication systems. In addition, in 5Gcommunication systems, development for system network improvement isunder way based on advanced small cells, cloud radio access networks(RANs), ultra-dense networks, device-to-device (D2D) communication,wireless backhaul, moving network, cooperative communication,coordinated multi-points (CoMP), reception-end interference cancellationand the like. In the 5G system, hybrid FSK and QAM (FQAM) and slidingwindow superposition coding (SWSC) as an advanced coding modulation(ACM), and filter bank multi carrier (FBMC), non-orthogonal multipleaccess (NOMA), and sparse code multiple access (SCMA) as an advancedaccess technology have been developed.

In the next generation wireless communication system operating in highfrequency bands, paging needs to be transmitted using beamforming.Paging transmission/reception using beamforming leads to increasedsignaling overhead and UE power consumption. So an enhanced method ofpaging transmission/reception is needed.

SUMMARY

To address the above-discussed deficiencies, it is designed a primaryobject to address at least the problems and/or disadvantages describedabove and to provide at least the advantages described below.

Accordingly, an aspect of the present disclosure is to provide a methodand apparatus for transmitting/receiving a paging message in a nextgeneration communication system, thereby improving the communicationsystem performance.

In accordance with an aspect of the present disclosure, a method forreceiving a paging message by a terminal is provided. The methodcomprises identifying a paging occasion in which a paging message is tobe received in a paging frame; and receiving the paging message, whichis transmitted on a transmission beam, on a reception beam in a pagingslot among a plurality of paging slots in the paging occasion, from abase station.

In accordance with another aspect of the present disclosure, a terminalreceiving a paging message is provided. The terminal comprises atransceiver to transmit and receive signals; and an at least oneprocessor configured to identify a paging occasion in which a pagingmessage is to be received in a paging frame, and to receive the pagingmessage, which is transmitted on a transmission beam, on a receptionbeam in a paging slot among a plurality of paging slots in the pagingoccasion, from a base station.

In accordance with another aspect of the present disclosure, a methodfor transmitting a paging message by a base station is provided. Themethod comprises identifying a paging occasion in which a paging messageis to be transmitted in a paging frame; and transmitting the pagingmessage on a transmission beam in a paging slot among a plurality ofpaging slots in the paging occasion, to a terminal.

In accordance with another aspect of the present disclosure, a basestation transmitting a paging message is provided. The base stationcomprises a transceiver to transmit and receive signals; and an at leastone processor configured to identify a paging occasion in which a pagingmessage is to be transmitted in a paging frame, and to transmit thepaging message on a transmission beam in a paging slot among a pluralityof paging slots in the paging occasion, to a terminal.

In accordance with another aspect of the present disclosure, a methodfor receiving a paging message by a terminal is provided. The methodcomprises transmitting a beam indication signal indicating atransmission beam, to a base station; and receiving a paging message,which is transmitted on the transmission beam indicated by the beamindication signal in a paging occasion, from the base station.

In accordance with another aspect of the present disclosure, a terminalreceiving a paging message is provided. The terminal comprises atransceiver to transmit and receive signals; and an at least oneprocessor configured to transmit a beam indication signal indicating atransmission beam, to a base station, and to receive a paging message,which is transmitted on the transmission beam indicated by the beamindication signal in a paging occasion, from the base station.

In accordance with another aspect of the present disclosure, a methodfor transmitting a paging message by a base station is provided. Themethod comprises receiving a beam indication signal indicating atransmission beam, from a terminal; and transmitting a paging message,which is transmitted on the transmission beam indicated by the beamindication signal in a paging occasion, to the terminal.

In accordance with another aspect of the present disclosure, a basestation transmitting a paging message is provided. The base stationcomprises a transceiver to transmit and receive signals; and an at leastone processor configured to receive a beam indication signal indicatinga transmission beam, from a terminal, and to transmit a paging message,which is transmitted on the transmission beam indicated by the beamindication signal in a paging occasion, to the terminal.

Before undertaking the DETAILED DESCRIPTION below, it may beadvantageous to set forth definitions of certain words and phrases usedthroughout this patent document: the terms “include” and “comprise,” aswell as derivatives thereof, mean inclusion without limitation; the term“or,” is inclusive, meaning and/or; the phrases “associated with” and“associated therewith,” as well as derivatives thereof, may mean toinclude, be included within, interconnect with, contain, be containedwithin, connect to or with, couple to or with, be communicable with,cooperate with, interleave, juxtapose, be proximate to, be bound to orwith, have, have a property of, or the like; and the term “controller”means any device, system or part thereof that controls at least oneoperation, such a device may be implemented in hardware, firmware orsoftware, or some combination of at least two of the same. It should benoted that the functionality associated with any particular controllermay be centralized or distributed, whether locally or remotely.Definitions for certain words and phrases are provided throughout thispatent document, those of ordinary skill in the art should understandthat in many, if not most instances, such definitions apply to prior, aswell as future uses of such defined words and phrases.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present disclosure and itsadvantages, reference is now made to the following description taken inconjunction with the accompanying drawings, in which like referencenumerals represent like parts:

FIG. 1 illustrates an embodiment of paging channel design according tovarious embodiments of the present disclosure;

FIG. 2 illustrates another embodiment of paging channel design accordingto various embodiments of the present disclosure;

FIG. 3 illustrates yet another embodiment of paging channel designaccording to various embodiments of the present disclosure;

FIG. 4 illustrates yet another embodiment of paging channel designaccording to various embodiments of the present disclosure;

FIG. 5 illustrates yet another embodiment of paging channel designaccording to various embodiments of the present disclosure;

FIG. 6 illustrates an embodiment of receiving a paging according tovarious embodiments of the present disclosure;

FIG. 7 illustrates another embodiment of receiving a paging according tovarious embodiments of the present disclosure;

FIG. 8 illustrates embodiment of receiving a paging according to variousembodiments of the present disclosure;

FIGS. 9A and 9B illustrate embodiments of receiving a paging accordingto various embodiments of the present disclosure;

FIGS. 10A and 10B illustrate embodiments of transmitting broadcastsignals according to various embodiments of the present disclosure;

FIG. 11 illustrates another embodiment of transmitting broadcast signalsaccording to various embodiments of the present disclosure;

FIG. 12 illustrates an embodiment of determining paging occasionaccording to various embodiments of the present disclosure;

FIG. 13 illustrates another embodiment of determining paging occasionaccording to various embodiments of the present disclosure;

FIG. 14 illustrates yet another embodiment of determining pagingoccasion according to various embodiments of the present disclosure;

FIG. 15 illustrates yet another embodiment of determining pagingoccasion according to various embodiments of the present disclosure;

FIG. 16 illustrates another embodiment of determining paging occasionaccording to various embodiments of the present disclosure;

FIG. 17 illustrates another embodiment of determining paging occasionaccording to various embodiments of the present disclosure;

FIG. 18 illustrates yet another embodiment of determining pagingoccasion according to various embodiments of the present disclosure;

FIG. 19 illustrates yet another embodiment of determining pagingoccasion according to various embodiments of the present disclosure;

FIG. 20 illustrates an embodiment of transmitting paging indicationaccording to various embodiments of the present disclosure;

FIG. 21 illustrates an embodiment of transmitting paging according tovarious embodiments of the present disclosure;

FIG. 22 illustrates another embodiment of transmitting paging accordingto various embodiments of the present disclosure;

FIG. 23 illustrates yet another embodiment of transmitting pagingaccording to various embodiments of the present disclosure;

FIG. 24 illustrates an embodiment of avoiding paging according tovarious embodiments of the present disclosure;

FIG. 25 illustrates another embodiment of avoiding paging according tovarious embodiments of the present disclosure;

FIG. 26 illustrates yet another embodiment of avoiding paging accordingto various embodiments of the present disclosure;

FIG. 27 illustrates an eNB apparatus according to various embodiments ofthe present disclosure; and

FIG. 28 illustrates a UE apparatus according to various embodiments ofthe present disclosure.

DETAILED DESCRIPTION

FIGS. 1 through 28, discussed below, and the various embodiments used todescribe the principles of the present disclosure in this patentdocument are by way of illustration only and should not be construed inany way to limit the scope of the disclosure. Those skilled in the artwill understand that the principles of the present disclosure may beimplemented in any suitably arranged system or device.

Various embodiments of the present disclosure will be described indetail with reference to the accompanying drawings. In the followingdescription, specific details such as detailed configurations andcomponents are merely provided to assist the overall understanding ofthese embodiments of the present disclosure. Therefore, it should beapparent to those skilled in the art that various changes andmodifications of the embodiments described herein can be made withoutdeparting from the scope and spirit of the present disclosure. Inaddition, descriptions of well-known functions and constructions areomitted for clarity and conciseness

In each drawing, the same or similar components may be denoted by thesame reference numerals.

Each block of the flow charts and combinations of the flow charts may beperformed by computer program instructions. Because these computerprogram instructions may be mounted in processors for a generalcomputer, a special computer, or other programmable data processingapparatuses, these instructions executed by the processors for thecomputer or the other programmable data processing apparatuses createmeans performing functions described in block(s) of the flow charts.Because these computer program instructions may also be stored in acomputer usable or computer readable memory of a computer or otherprogrammable data processing apparatuses in order to implement thefunctions in a specific scheme, the computer program instructions storedin the computer usable or computer readable memory may also producemanufacturing articles including instruction means performing thefunctions described in block(s) of the flow charts. Because the computerprogram instructions may also be mounted on the computer or the otherprogrammable data processing apparatuses, the instructions performing aseries of operation steps on the computer or the other programmable dataprocessing apparatuses to create processes executed by the computer tothereby execute the computer or the other programmable data processingapparatuses may also provide steps for performing the functionsdescribed in block(s) of the flow charts.

In addition, each block may indicate a module, a segment, and/or a codeincluding one or more executable instructions for executing a specificlogical function(s). Further, functions mentioned in the blocks occurregardless of a sequence in some alternative embodiments. For example,two blocks that are consecutively illustrated may be simultaneouslyperformed in fact or be performed in a reverse sequence depending oncorresponding functions sometimes.

Herein, the term “unit” may include software and/or hardware components,such as a field-programmable gate array (FPGA) and/or anapplication-specific integrated circuit (ASIC). However, the meaning of“unit” is not limited to software and/or hardware. For example, a unitmay be configured to be in a storage medium that may be addressed andmay also be configured to reproduce one or more processor. Accordingly,a “unit” may include components such as software components, objectoriented software components, class components, task components,processors, functions, attributes, procedures, subroutines, segments ofprogram code, drivers, firmware, microcode, circuit, data, database,data structures, tables, arrays, and variables.

Functions provided in the components and the “units” may be combinedwith a smaller number of components and/or “units” or may furtherseparate into additional components and/or “units”.

In addition, components and units may also be implemented to reproduceone or more CPUs within a device or a security multimedia card.

The terms as used in the present disclosure are provided to describespecific embodiments, and do not limit the scope of other embodiments.It is to be understood that singular forms include plural forms unlessthe context clearly dictates otherwise. Unless otherwise defined, theterms and words including technical or scientific terms used in thefollowing description and claims may have the same meanings as generallyunderstood by those skilled in the art. The terms as generally definedin dictionaries may be interpreted as having the same or similarmeanings as the contextual meanings of related technology. Unlessotherwise defined, the terms should not be interpreted as ideally orexcessively formal meanings. When needed, even the terms as defined inthe present disclosure may not be interpreted as excluding embodimentsof the present disclosure.

Herein, a base station performs resource allocation to a terminal.Examples of the base station may include an eNodeB (eNB), a Node B,gNodeB (gNB), transmission reception point (TRP), a wireless accessunit, a base station controller, a node on a network, etc. Examples ofthe terminal may include a user equipment (UE), a mobile station (MS), acellular phone, a smart phone, a computer, a multimedia systemperforming a communication function, etc.

Herein, a downlink (DL) is a radio transmission path of a signal from abase station to a UE and an uplink (UL) is a radio transmission path ofa signal from the UE to the base station.

The embodiments of the present disclosure may be applied to othercommunication systems having similar technical backgrounds or channelforms.

A method of providing a generally high throughput and capacity includesa method of providing communication using a wider frequency band and amethod of increasing frequency usage efficiency. However, it is verydifficult to provide a higher average data rate through the lattermethod. This is because communication technologies of a currentgeneration provide frequency usage efficiency close to a theoreticallimit and thus, it is very difficult to increase the frequency usageefficiency up to that or more through a technical improvement.Accordingly, it can be said that a feasible method for increasingthroughput and capacity is a method of providing data services throughthe wider frequency band. At this time, the thing to consider is anavailable frequency band. In view of the current frequency distributionpolicy, a band in which a broadband communication of 1 GHz or more ispossible is limited and a practically selectable frequency band is onlythe millimeter wave band of 28 GHz or more. The signal transmitted onthe high frequency band suffers from huge path losses and propagationlosses compared to a signal transmitted on a frequency band of 2 GHz orlower used by the conventional cellular systems. This significantlyreduces the coverage of a base station using the same power as theconventional cellular systems.

Beamforming techniques are used to mitigate the propagation path lossand to increase the propagation distance for communication at higherfrequency. Beamforming enhances the transmission and receptionperformance using a high-gain antenna. Beamforming can be classifiedinto transmission (TX) beamforming performed in a transmitting end andreception (RX) beamforming performed in a receiving end. In general, theTX beamforming increases directivity by allowing an area in whichpropagation reaches to be densely located in a specific direction byusing a plurality of antennas. In this situation, aggregation of theplurality of antennas can be referred to as an antenna array, and eachantenna included in the array can be referred to as an array element.The antenna array can be configured in various forms such as a lineararray, a planar array, etc. The use of the TX beamforming results in theincrease in the directivity of a signal, thereby increasing apropagation distance. Further, since the signal is almost nottransmitted in a direction other than a directivity direction, a signalinterference acting on another receiving end is significantly decreased.The receiving end can perform beamforming on a RX signal by using a RXantenna array. The RX beamforming increases the RX signal strengthtransmitted in a specific direction by allowing propagation to beconcentrated in a specific direction, and excludes a signal transmittedin a direction other than the specific direction from the RX signal,thereby providing an effect of blocking an interference signal.

By using beamforming technique, a transmitter can make plurality oftransmit beam patterns of different directions. Each of these transmitbeam patterns can be also referred as transmit (TX) beam. Wirelesscommunication system operating at high frequency uses plurality ofnarrow TX beams to transmit signals in the cell as each narrow TX beamprovides coverage to a part of cell. The narrower the TX beam, higher isthe antenna gain and hence the larger the propagation distance of signaltransmitted using beamforming. A receiver can also make plurality ofreceive (RX) beam patterns of different directions. Each of thesereceive patterns can be also referred as receive (RX) beam.

In the existing wireless communication system the paging is transmittedto page UE which are attached to the wireless communication network butare in idle or inactive mode. In the idle or inactive mode UE wake upsat regular intervals (every paging DRX cycle) for short periods toreceive paging and other broadcast information. In legacy system UEmonitor one paging occasion (PO) every DRX cycle. One PO is asubframe/TTI of 1 ms duration. The paging message including UE ID of thepaged UE is transmitted only in PO monitored by the paged UE. Networkmay configure several POs in a DRX cycle. The UE determines the UE's PObased on a UE ID. A UE first determines the paging frame (PF) and thendetermine the PO within the PF. One PF is radio frame (10 ms), which maycontain one or multiple POs. Every radio frame in a DRX cycle can bepaging frame. There can be up to four POs in a PF. The subframes whichcan be PO in a PF are pre-defined i.e. subframe #0, subframe #4,subframe #5 and subframe #9. The network (i.e. BS) signals twoparameters. The first parameter is ‘T’ i.e. paging DRX cycle duration inradio frames. The second parameter is ‘nB’ i.e. number of POs in apaging DRX cycle. UEs are distributed across several ‘nB’ POs in the DRXcycle based on a UE ID. Several UEs can be mapped to same PO. The PF fora UE is the radio frame with system frame number ‘SFN’ which satisfiesthe equation SFN mod T=(T div N)*(UE_ID mod N); where N is equal to min(T, nB) and a UE_ID is equal to IMSI mod 1024. Within the determined PF,the PO corresponds to i_s=floor(UE_ID/N) mod Ns; where Ns is equal tomax (1, nB/T); i_s can be 0, 1, 2 and 3. Mapping between i_s, Ns andsubframe within paging frame is pre-defined. In a PO, paging message istransmitted using physical downlink shared channel (PDSCH). Physicaldownlink common control channel (PDCCH) is addressed to P-RNTI if thereis a paging message in PDSCH. P-RNTI is common for all UEs. So a UEidentity (i.e. IMSI or S-TMSI) is included in paging message to indicatepaging for a specific UE. Paging message may include multiple UEidentities to page multiple UEs. Paging message is broadcasted (i.e.PDCCH is masked with P-RNTI) over data channel (i.e. PDSCH).

In case of high frequency band, paging needs to be transmitted usingbeamforming. At higher frequencies, beamforming is essential tocompensate for path loss. One TX beam cannot provide the full cellcoverage. Paging needs to be transmitted using the multiple transmissionbeams. In case of paging transmission/reception using beamforming, asystem and method is needed to address issues such as definition ofpaging occasion, paging transmission mechanism in paging occasion,determination of paging occasion by a UE, determination of TX/RX beamsfor paging reception by a UE, determination of TX beams for pagingtransmission by network, and so on.

In the existing wireless communication system, UE monitors one pagingoccasion (PO) every paging DRX cycle wherein one PO has one time slot orpaging time slot. The duration of time slot is 1 ms. In the presentdisclosure, UE monitors one PO every paging DRX cycle wherein one PO hasone or more paging time slots. The number of paging time slots in PO isconfigured by network. The configuration can be signaled in systeminformation and/or in dedicated RRC signaling. In a PO, the paging timeslots can be contiguous or non-contiguous. For example, network canindicate that PO duration is ‘n’ time slots and each time slot is apaging time slot. Network can indicate that PO duration is ‘n’ timeslots and also indicate which of these ‘n’ time slots are paging timeslot (i.e. time slot in which paging is transmitted). The paginginformation (e.g. paging message and/or paging indicator) transmitted ineach paging time slot of PO is same. The DL TX beam(s) used in eachpaging time slot can be different. The PO can also be referred as pagingburst or paging burst set or PO interval or paging burst interval. Thevarious embodiments illustrating the PO structure for transmittingpaging using beamforming is explained below:

FIG. 1 illustrates an embodiment of paging channel design according tovarious embodiments of the present disclosure.

Each paging occasion (PO, 110) comprises of one or more paging blocks(120, 130 and 140). These paging blocks can be consecutive or staggered.Each paging block comprises of one or more paging slots (121, 123, 125,127 and 129). These paging slots can be consecutive or staggered.

In an embodiment, there can be N consecutive paging blocks in a PO andone or more paging block(s) amongst these which carry paging can besignaled or pre-defined. N can be signaled by network in RRC signalingor in BCH or in system information or can be pre-defined. Alternately,PO duration and duration of each paging block can be signaled by networkin RRC signaling or in BCH or in system information. Number of pagingblocks is equal to PO duration divided by duration of each paging block.Alternately, PO duration and N can be signaled by network. In this casethere are N consecutive paging blocks and PO duration can be greaterthan N*length of each paging block. A bit map can be used to signalwhich paging block amongst the N paging blocks in PO are used forpaging. Alternately, paging block number (each paging block in PO can besequentially numbered starting from zero) can be used to explicitlyindicate paging block(s) used for paging. Paging block which carrypaging can be at a fixed offset from synchronization signal (SS) blockcarrying other signals (such as primary synchronization signal/secondarysynchronization signal/extended synchronization signal/broadcast channelPSS/SSS/ESS/BCH), etc).

In an alternate embodiment, there can be N paging blocks in a PO where Nis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The first paging block (120) startsfrom the start of PO (110). There is an offset between paging blocks andis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The offset between paging blocks canalso be zero. In case offset between paging blocks is zero the offsetmay or may not be signaled by network. PO duration can also be signaledby network in RRC signaling or in BCH or in system information.

In an alternate embodiment, there can be N paging blocks in a PO where Nis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The first paging block (120) startsat an offset from the start of PO (110) and is signaled by network inRRC signaling or in BCH or in system information. There is an offsetbetween paging blocks in PO and is signaled by network in RRC signalingor in BCH or in system information or can be pre-defined. The offsetbetween paging blocks can also be zero. In case offset between pagingblocks is zero the offset may or may not be signaled by network. Theoffset between paging blocks and offset between start of PO and firstpaging block can be same. PO duration can also be signaled by network inRRC signaling or in BCH or in system information.

In an alternate embodiment, there can be N paging blocks in a PO.Network signals the PO duration and duration of paging block in RRCsignaling or in BCH or in system information. Number of paging blocks isequal to PO duration divided by ‘offset +duration of each paging block’.The first paging block (120) starts at an offset from the start of PO(110) and is signaled by network in RRC signaling or in BCH or in systeminformation. There is an offset between paging blocks in PO and issignaled by network in RRC signaling or in BCH or in system informationor can be pre-defined. The offset between paging blocks can also bezero. In case offset between paging blocks is zero the offset may or maynot be signaled by network. The offset between paging blocks and offsetbetween start of PO and first paging block can be same.

In an alternate embodiment, there can be N paging blocks in a PO.Network signals the PO duration, duration of paging block and pagingblock period in RRC signaling or in BCH or in system information. Onepaging block is there every paging block period in PO. Paging blockperiod starts from start of PO. Number of paging blocks is equal to POduration divided by ‘paging block period’.

In an embodiment, there can be N consecutive paging blocks in a PO andall paging block(s) carry paging.

Each paging slot (PS, 121, 123, 125, 127 and 129) comprises of one ormore orthogonal frequency division multiplexing OFDM) symbols. Thenumber of OFDM symbols in each PS can be pre-defined or signaled bynetwork in RRC signaling or in BCH or in system information. The numberof PSs in each paging block can be pre-defined or signaled by network inRRC signaling or in BCH or in system information. Alternately number ofPSs is equal to paging block duration divided by duration of each PS.These PSs can be consecutive or staggered in a paging block. Similar tosignaling mechanism to indicate which paging blocks in a PO are used forpaging, PSs in a paging block used for paging can be signaled asexplained above.

In an embodiment of FIG. 1, other signals (such as PSS/SSS/ESS/BCH,etc.) can be transmitted frequency division multiplexing (FDM)/codedivision multiplexing (CDM)/time division multiplexing (TDM) togetherwith paging in PS. Paging can be transmitted in specific physicalresource block (PRB)s or all PRBs in each PS. If paging is transmittedin specific PRBs then these PRBs can be pre-defined or signaled bynetwork in RRC signaling or in BCH or in system information.

Paging information (e.g. paging message) is transmitted using one ormore DL TX beams in each PS. Mapping between PS and DL TX beam(s) can bepre-defined or signaled by network in RRC signaling or in BCH or insystem information. Alternately, mapping between PS(s) and SS block(s)can be pre-defined (e.g. SS block 1 mapped to PS1, SS block 2 mapped toPS 2 and so on) or signaled. Each PS can be mapped to one or more SSblocks or DL TX beams. Alternately, mapping between paging block(s) andDL TX beam(s) can be pre-defined or signaled. Alternately, mappingbetween paging block and SS block(s) can be pre-defined (e.g. SS block 1mapped to paging block 1, SS block 2 mapped to paging block 2 and so on)or signaled. Each paging block can be mapped to one or more SS blocks orDL TX beams. In an embodiment, network may indicate whether DL TX beamsused for transmission of PSS/SSS/PBCH is quasi-collocated (QCL) withthose used for transmission of paging or not. If not, then UE monitorsall paging slots in PO. If yes, then a UE can identify the pagingslot(s) or paging block(s) corresponding to best/suitable DL TX beam orSS block and only monitor that. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple DL TX beams then TX beam with strongest signal quality is thebest DL TX beam. If the signal quality of received signal from a DL TXbeam is above a certain threshold then the signal quality of receivedsignal is a suitable DL TX beam. The threshold can be signaled bynetwork in system information. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple SS blocks then SS block in which the UE has received signalswith strongest signal quality is the best SS block. If the signalquality of received signal from a SS block is above a certain thresholdthen the signal quality of received signal is a suitable SS block. Thethreshold can be signaled by network in system information.

In each PS one or more paging channels can be transmitted. Each pagingchannel can be of fixed size (e.g. transmitted over fixed number ofPRBs). This can reduce decoding complexity. Alternately paging channelcan be of variable size which is signaled by the PDCCH or MAC/RRCsignaling for example, if the size changes semi-statically. The pagingblock in this embodiment can also be a subframe or set of subframes.

FIG. 2 illustrates another embodiment of paging channel design accordingto various embodiments of the present disclosure.

Each paging occasion comprises of one or more paging slots. These pagingslots can be consecutive or staggered. All paging slots in PO carrypaging. Alternately, paging slot which carry paging in PO can besignaled or pre-defined in RRC signaling or in BCH or in systeminformation. The duration of paging slot can be pre-defined or signaledby network in RRC signaling or in BCH or in system information.

In an embodiment, there can be N consecutive paging slots (220, 230 and240) in a PO (210) and one or more paging slots amongst these whichcarry paging can be signaled or pre-defined in RRC signaling or in BCHor in system information. N can be signaled by network in RRC signalingor in BCH or in system information or can be pre-defined. Alternately,PO duration can be signaled by network in RRC signaling or in BCH or insystem information. Number of paging slots is equal to PO durationdivided by duration of each paging slot. Duration of paging slot can bepre-defined or can also be signaled by network RRC signaling or in BCHor in system information. Alternately, PO duration and N can be signaledby network. In this case there are N consecutive paging slots and POduration can be greater than N*length of each paging slot. A bit map canbe used to signal which paging slots amongst the N consecutive pagingslots in PO are used for paging. Alternately, paging slot number (eachpaging slot in PO can be sequentially numbered starting from zero) canbe used to explicitly indicate paging slots used for paging. Paging slotwhich carry paging can be at a fixed offset from SS block carrying othersignals (such as PSS/SSS/ESS/BCH, etc).

In an alternate embodiment, there can be N paging slots (220, 230 and240) in a PO (210) where N is signaled by network in RRC signaling or inBCH or in system information or can be pre-defined. The first pagingslot (220) starts from the start of PO (210). There is an offset betweenpaging slots and is signaled by network in RRC signaling or in BCH or insystem information. The offset between paging slots can also be zero. Incase offset between paging slots is zero the offset may or may not besignaled by network. PO duration can also be signaled by network in RRCsignaling or in BCH or in system information.

In an alternate embodiment, there can be N paging slots (220, 230 and240) in a PO (210) where N is signaled by network in RRC signaling or inBCH or in system information or can be pre-defined. The first pagingslot (220) starts at an offset from the start of PO (210) and offset issignaled by network in RRC signaling or in BCH or in system informationor can be pre-defined. There is an offset between paging slots in PO andis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The offset between paging slots canalso be zero. In case offset between paging slots is zero the offset mayor may not be signaled by network. The offset between paging slots andoffset between start of PO and first paging slot can be same. POduration can also be signaled by network in RRC signaling or in BCH orin system information.

In an alternate embodiment, there can be N paging slots (220, 230 and240) in a PO (210). Network signals the PO duration and duration ofpaging slot in RRC signaling or in BCH or in system information. Numberof paging slots is equal to PO duration divided by ‘offset +duration ofeach paging slot. The first paging slot (220) starts at an offset fromthe start of PO (210) and offset is signaled by network in RRC signalingor in BCH or in system information or can be pre-defined. There is anoffset between paging slots in PO and is signaled by network in RRCsignaling or in BCH or in system information or can be pre-defined. Theoffset between paging slots can also be zero. In case offset betweenpaging slots is zero the offset or may not be signaled by network. Theoffset between paging slots and offset between start of PO and firstpaging slot can be same.

In an alternate embodiment, there can be N paging slots in a PO. Networksignals the PO duration, duration of paging slot and paging slot periodin RRC signaling or in BCH or in system information. One paging slot isthere every paging slot period in PO. Paging slot period starts fromstart of PO. Number of paging slots is equal to PO duration divided by‘paging slot period’.

Paging is transmitted using PDCCH/EPDCCH/xPDCCH (222) and PDSCH (224) ina paging slot. Guard band and PUSCH/PUCCH region may also be there inpaging slot. In a paging slot, PDCCH/EPDCCH/xPDCCH (222) masked withP-RNTI indicates that paging is there in PDSCH (224).PDCCH/EPDCCH/xPDCCH (222) and PDSCH (224) in paging slot are transmittedusing one or more DL TX beams. The P-RNTI can be common for all UEs.Alternately there can be several P-RNTIs. A UE selects a P-RNTI based onthe UE's UE ID. A UE selects the ith P-RNTI in list of P-RNTIs wherei=UE ID mod P where ‘P’ is number of P-RNTIs in the list. P-RNTI to beused by a UE can also be assigned to a UE. The list of P-RNTIs can bepre-defined or signaled by network in RRC signaling or in BCH or insystem information.

Paging information (e.g. paging message) is transmitted using one ormore DL TX beams in each paging slot. Same paging information istransmitted in each paging slot of PO. The mapping between paging slotsand DL TX beam(s) can be pre-defined or signaled in a broadcast ordedicated manner. Alternately, mapping between paging slots and SSblock(s) can be pre-defined (e.g. SS block 1 mapped to PS1, SS block 2mapped to PS 2 and so on) or signaled. Each paging slot can be mapped toone or more SS blocks or DL TX beams. In an embodiment, network mayindicate whether DL TX beams used for transmission of PSS/SSS/PBCH isquasi-collocated (QCL) with those used for transmission of paging ornot. If not, then a UE monitors all paging slots in PO. If yes, then aUE can identify the paging slot(s) corresponding to best/suitable DL TXbeam or SS block and only monitor that. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple DL TX beams then TX beam with strongest signal quality is thebest DL TX beam. If the signal quality of received signal from a DL TXbeam is above a certain threshold then the signal quality of receivedsignal is a suitable DL TX beam. The threshold can be signaled bynetwork in system information. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple SS blocks then SS block in which the UE has received signalswith strongest signal quality is the best SS block. If the signalquality of received signal from a SS block is above a certain thresholdthen the signal quality of received signal is a suitable SS block. Thethreshold can be signaled by network in system information.

FIG. 3 illustrates another embodiment of paging channel design accordingto various embodiments of the present disclosure.

Each paging occasion (PO, 310) comprises of one or more paging blocks(320, 330 and 340). These paging blocks can be consecutive or staggered.Each paging block comprises of one or more paging slots (322, 324, 326and 328). These paging slots can be consecutive or staggered in a pagingblock.

In an embodiment, there can be N consecutive paging blocks in a PO andone or more paging block(s) amongst these which carry paging can besignaled or pre-defined. N can be signaled by network in RRC signalingor in BCH or in system information or can be pre-defined. Alternately,PO duration and duration of each paging block can be signaled by networkin RRC signaling or in BCH or in system information. Number of pagingblocks is equal to PO duration divided by duration of each paging block.Alternately, PO duration and N can be signaled by network. In this casethere are N consecutive paging blocks and PO duration can be greaterthan N*length of each paging block. A bit map can be used to signalwhich paging block amongst the N consecutive paging blocks in PO areused for paging. Alternately, paging block number (each paging block inPO is sequentially numbered starting from zero) can be used toexplicitly indicate paging block(s) used for paging. Paging block whichcarry paging can be at a fixed offset from SS block carrying othersignals (such as PSS/SSS/ESS/BCH, etc.).

In an alternate embodiment, there can be N paging blocks in a PO where Nis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The first paging block (320) startsfrom the start of PO (310). There is an offset between paging blocks andis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The offset between paging blocks canalso be zero. In case offset between paging blocks is zero the offsetmay or may not be signaled by network. PO duration can also be signaledby network in RRC signaling or in BCH or in system information.

In an alternate embodiment, there can be N paging blocks in a PO where Nis signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. The first paging block (320) startsat an offset from the start of PO (310). There is an offset betweenpaging blocks in PO and is signaled by network in RRC signaling or inBCH or in system information or can be pre-defined. The offset betweenpaging blocks can also be zero. In case offset between paging blocks iszero the offset may or may not be signaled by network. The offsetbetween paging blocks and offset between start of PO and first pagingblock can be same. PO duration can also be signaled by network in RRCsignaling or in BCH or in system information.

In an alternate embodiment, there can be N paging blocks in a PO.Network signals the PO duration and duration of paging block in RRCsignaling or in BCH or in system information. Number of paging blocks isequal to PO duration divided by ‘offset +duration of each paging block’.The first paging block (120) starts at an offset from the start of PO(110) and is signaled by network in RRC signaling or in BCH or in systeminformation. There is an offset between paging blocks in PO and issignaled by network in RRC signaling or in BCH or in system informationor can be pre-defined. The offset between paging blocks can also bezero. In case offset between paging blocks is zero the offset may or maynot be signaled by network. The offset between paging blocks and offsetbetween start of PO and first paging block can be same.

In an alternate embodiment, there can be N paging blocks in a PO.Network signals the PO duration, duration of paging block and pagingblock period in RRC signaling or in BCH or in system information. Onepaging block is there every paging block period in PO. Paging blockperiod starts from start of PO. Number of paging blocks is equal to POduration divided by ‘paging block period’.

In an embodiment, there can be N consecutive paging blocks in a PO andall paging block(s) carry paging.

Paging is transmitted using PDCCH/EPDCCH/xPDCCH (322, 326) and PDSCH(324, 328) in each paging slot in a paging block (320). Guard band andPUSCH/PUCCH region may also be there in paging slot. In a paging slot,PDCCH/EPDCCH/xPDCCH (322, 326) masked with P-RNTI indicates that pagingis there in PDSCH (324, 328). PDCCH/EPDCCH/xPDCCH (322, 326) and PDSCH(324, 328) in paging slot are transmitted using one or more DL TX beams.The P-RNTI can be common for all UEs. Alternately there can be severalP-RNTIs. A UE selects a P-RNTI based on the UE's UE ID. A UE selects theith P-RNTI in list of P-RNTIs where i=UE ID mod P where ‘P’ is number ofP-RNTIs in the list. P-RNTI to be used by a UE can also be assigned tothe UE. The list of P-RNTIs can be pre-defined or signaled by network inRRC signaling or in BCH or in system information. The number of PSs ineach paging block can be pre-defined or signaled by network in RRCsignaling or in BCH or in system information. Alternately number of PS sis equal to paging block duration divided by duration of each PS. ThesePSs can be consecutive or staggered in a paging block. Similar tosignaling mechanism to indicate which paging blocks in a PO are used forpaging, PSs in a paging block used for paging can be signaled asexplained above.

Other signals (such as PSS/SSS/ESS/BCH, etc.) can be transmitted(FDM/CDM/TDM) together with paging in PS. Paging can be transmitted inspecific PRBs or all PRBs in each PS. If paging is transmitted inspecific PRBs then these PRBs can be pre-defined or signaled by networkin RRC signaling or in BCH or in system information.

Paging information (e.g. paging message) is transmitted using one ormore DL TX beams in each PS. The same paging information is transmittedin each PS of PO. The mapping between PS and DL TX beam(s) can bepre-defined or signaled. Alternately, mapping between PS and SS block(s)can be pre-defined (e.g. SS block 1 mapped to PS1, SS block 2 mapped toPS 2 and so on) or signaled. Alternately, mapping between paging blockand DL TX beam(s) can be pre-defined or signaled. Alternately, mappingbetween paging block and SS block(s) can be pre-defined (e.g. SS block 1mapped to paging block 1, SS block 2 mapped to paging block 2 and so on)or signaled. Each paging slot can be mapped to one or more SS blocks orDL TX beams. In an embodiment, network may indicate whether DL TX beamsused for transmission of PSS/SSS/PBCH is quasi-collocated (QCL) withthose used for transmission of paging or not. If not, then a UE monitorsall paging slots in PO. If yes, then the UE can identify the pagingslot(s) corresponding to best/suitable DL TX beam or SS block and onlymonitor that. If a UE is able to receive synchronization signals and/orbroadcast channel successfully from multiple DL TX beams then TX beamwith strongest signal quality is the best DL TX beam. If the signalquality of received signal from a DL TX beam is above a certainthreshold then the signal quality of received signal is a suitable DL TXbeam. The threshold can be signaled by network in system information. Ifa UE is able to receive synchronization signals and/or broadcast channelsuccessfully from multiple SS blocks then SS block in which is hasreceived signals with strongest signal quality is the best SS block. Ifthe signal quality of received signal from a SS block is above a certainthreshold then the signal quality of received signal is a suitable SSblock. The threshold can be signaled by network in system information.

The paging block in this embodiment can also be a subframe or set ofsubframes.

FIG. 4 illustrates another embodiment of paging channel design accordingto various embodiments of the present disclosure.

Each paging occasion (410) comprises of one or more paging slot set(420, 430). These paging slot sets can be consecutive or staggered. Eachpaging slot set (420) consists of one or more paging slots (424, 426,428 and 429). Paging slot set which carry paging can be signaled orpre-defined.

In an embodiment, there can be N consecutive paging slot sets in a POand one or more paging slot sets amongst these which carry paging can besignaled or pre-defined in RRC signaling or in BCH or in systeminformation. N can be signaled by network in RRC signaling or in BCH orin system information or can be pre-defined. Alternately, PO durationand duration of each paging slot set can be signaled by network in RRCsignaling or in BCH or in system information. Number of paging slot setsis equal to PO duration divided by duration of each paging slot set. Abit map can be used to signal which paging slot set amongst the Nconsecutive paging slots in PO are used for paging. Alternately, pagingslot set number (each paging slot set in PO is sequentially numberedstarting from zero) can be used to explicitly indicate paging slot setsused for paging. Paging slot set which carry paging can be at a fixedoffset from SS block carrying other signals (such as PSS/SSS/ESS/BCH,etc.).

In an alternate embodiment, there can be N paging slot set in a PO whereN is signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. N can be one also. The first pagingslot set (420) starts from the start of PO (40). There is an offsetbetween paging slot set and is signaled by network in RRC signaling orin BCH or in system information. The offset between paging slot sets canalso be zero. In case offset between paging slot sets is zero the offsetmay or may not be signaled by network.

In an alternate embodiment, there can be N paging slot sets in a POwhere N is signaled by network in RRC signaling or in BCH or in systeminformation or can be pre-defined. N can be one also. The first pagingslot set (420) starts at an offset from the start of PO (410). There isan offset between paging slot set in PO and is signaled by network inRRC signaling or in BCH or in system information or can be pre-defined.The offset can also be zero. In case offset between paging slot sets iszero the offset may or may not be signaled by network. The offsetbetween paging slot sets and offset between start of PO and first pagingslot set can be same.

In an alternate embodiment, there can be N paging slot sets in a PO.Network signals the PO duration and duration of paging slot set in RRCsignaling or in BCH or in system information. Number of paging slot setsis equal to PO duration divided by “offset +duration of each paging slotset.” The first paging slot set (420) starts at an offset from the startof PO (410). There is an offset between paging slot set in PO and issignaled by network in RRC signaling or in BCH or in system informationor can be pre-defined. The offset can also be zero. In case offsetbetween paging slot sets is zero the offset may or may not be signaledby network. The offset between paging slot sets and offset between startof PO and first paging slot set can be same.

In an alternate embodiment, there can be N paging slot sets in a PO.Network signals the PO duration, duration of paging slot set and pagingslot set period in RRC signaling or in BCH or in system information. Onepaging slot set is there every paging slot set period in PO. Paging slotset period starts from start of PO. Number of paging slot sets is equalto PO duration divided by “paging slot set period.”

Paging is transmitted using PDCCH/EPDCCH/xPDCCH (422) and PDSCH (424,426, 428 and 429). PDCCH/EPDCCH/xPDCCH (422) indicates each of resourcesfor PDSCH (424, 426, 428 and 429) in multiple paging slots. In a pagingslot set (420), PDCCH/EPDCCH/xPDCCH (422) masked with P-RNTI indicatesthat paging is there in PDSCH (424, 426, 428 and 429) of specific pagingslot. PDCCH/EPDCCH/xPDCCH (422) in paging slot set is transmitted usingone or more DL TX beams in TDM and/or FDM manner. PDSCH (424, 426, 428and 429) in a paging slot are transmitted using one or more DL TX beams.The P-RNTI can be common for all UEs. Alternately there can be severalP-RNTIs. A UE selects a P-RNTI based on the UE's UE ID. A UE selects theith P-RNTI in list of P-RNTIs where i=UE ID mod P where ‘P’ is number ofP-RNTIs in the list. P-RNTI to be used by a UE can also be assigned tothe UE. The list of P-RNTIs can be pre-defined or signaled by network inRRC signaling or in BCH or in system information.

Paging information (e.g. paging message) is transmitted using one ormore DL TX beams in each PS. The same paging information is transmittedin each PS of PO. The, mapping between paging slot set and DL TX beam(s)can be pre-defined or signaled in a broadcast or dedicated manner.Alternately, mapping between paging slot set and SS block(s) can bepre-defined (e.g. SS block 1 mapped to paging slot set 1, SS block 2mapped to paging slot set 2 and so on) or signaled. In an embodiment,network may indicate whether DL TX beams used for transmission ofPSS/SSS/PBCH is quasi-collocated (QCL) with those used for transmissionof paging or not. If not, then a UE monitors all paging slot sets in PO.If yes, then a UE can identify the paging slot set(s) corresponding tobest/suitable DL TX beam or SS block and only monitor that.

FIG. 5 illustrates another embodiment of paging channel design accordingto various embodiments of the present disclosure.

Each paging occasion (510) comprises of one or more long subframes (520,530, 540). Size of each long subframe is multiple of subframe size.These subframes can be consecutive or staggered. Subframe which carrypaging can be signaled or pre-defined. Paging is transmitted usingPDCCH/EPDCCH/xPDCCH (522) and PDSCH (524) in a subframe. In a subframe,PDCCH/EPDCCH/xPDCCH (522) masked with P-RNTI indicates that paging isthere in PDSCH (524). PDCCH (522) and PDSCH (524) in subframe aretransmitted using one or more DL TX beams. Mapping between pagingsubframe and beam(s) can be pre-defined or signaled.

The grant allocation (DCI formats) for such long subframes is defined toaccount for the size of the subframe. Alternatively the grant allocationis scaled proportional to the size of the subframe in the units ofnormal subframe size.

In order to receive the paging message transmitted using beam sweeping,a UE has to monitor increased number of time slots for paging as POconsists of several time slots for TX beam sweeping. This leads toincrease the UE's power consumption. To solve this problem, embodimentsto minimize the UE's power consumption for receiving paging aredescribed below.

FIG. 6 and FIG. 7 illustrate an embodiment of receiving a pagingaccording to various embodiments of the present disclosure.

The embodiment illustrated in FIGS. 6 and 7 of the method to minimizeUE's power consumption is as follows: In this embodiment, based on theconfigured DRX cycle, a UE determines the start of paging frame orpaging occasion or paging burst in which paging is transmitted for theUE. A UE wakes up “N” broadcast periods before the start of paging frameor paging occasion or paging burst (610). The broadcast period (620) isthe interval over which BS/eNB/TRP completes one full TX beam sweepingfor synchronization signals (such as PSS/SSS/ESS) and broadcast channel(PBCH) transmission. “N” is the number of RX beams in a UE. During the“N” broadcast periods a UE tries to receive synchronization signals andbroadcast channel transmitted using plurality of TX beams usingplurality of RX beams. A UE determines the suitable or best TX/RX beampair. Suitable TX beam is the DL TX beam corresponding tosynchronization signals and/or broadcast channel successfully receivedby a UE. Suitable or best RX beam is the RX beam which was used tosuccessfully receive synchronization signals and/or broadcast channel.If a UE is able to receive synchronization signals and/or broadcastchannel successfully from multiple DL TX beams then TX beam withstrongest signal quality is the best DL TX beam. If the signal quality(or signal strength) of received signal from a DL TX beam is above acertain threshold then the signal quality of received signal is asuitable DL TX beam. The threshold can be signaled by network in systeminformation.

In the paging frame or paging occasion or paging burst (610), a UEreceives the paging as follows:

a) a UE monitors the time slot (s) corresponding to suitable and or bestDL TX beam using the suitable or best RX beam. Mapping between timeslot(s) and DL TX beam(s) can be signaled by network or can bepre-defined. A UE checks for PDCCH/EPDCCH/xPDCCH corresponding to pagingRNTI. If PDCCH/EPDCCH/XPDCCH corresponding to paging RNTI is received, AUE receives the Paging message in PDSCH using the information in thereceived PDCCH/EPDCCH/XPDCCH. PDCCH/EPDCCH/XPDCCH may indicate resourcesfor multiple time slots and a UE receives paging in PDSCH in these timeslots as described from FIG. 2 to FIG. 5. This procedure is illustratedin FIG. 6.

b) a UE monitors the paging slots corresponding to suitable and or DL TXbeam using the RX beam in the paging frame or paging occasion or pagingburst (710). Paging frame or paging occasion or paging burst (710) canhave many paging slots. Paging slot comprises of one or more OFDMsymbols. The paging frame or paging occasion or paging burst (710) canbe same as frame or paging occasion or burst in which synchronizationsignals (PSS/SSS/ESS) and broadcast channel (PBCH) is transmitted or thepaging frame or paging occasion or paging burst (710) can be anotherpaging frame or paging occasion or paging burst pre-defined or signaledby network. Differently from the procedure in FIG. 6, a mapping betweenpaging slots in paging frame or paging occasion or paging burst and DLTX beam can be signaled by network or can be pre-defined. This procedureis illustrated in FIG. 7. In the case when the paging frame or pagingoccasion or paging burst is same as frame or occasion or burst (710) inwhich synchronization signals (PSS/SSS/ESS) and broadcast channel (PBCH)is transmitted, a UE can wakeup ‘N−1’ broadcast periods instead of N.

FIG. 8 illustrates another embodiment of receiving a paging according tovarious embodiments of the present disclosure.

The embodiment illustrated in FIG. 8 of the method to minimize UE'spower consumption is as follows: a UE power consumption can be reducedif the UE can determine the best/suitable DL TX beam using the broadcastsignals such NR-PSS/SSS/PBCH and then monitors the time slot in POcorresponding to the best/suitable DL TX beam. If the signal quality ofreceived signal from a DL TX beam is above a certain threshold then thesignal quality of received signal is a suitable DL TX beam. Thethreshold can be signaled by network in system information. Note that aUE anyways have to monitor the broadcast signals such as NR-PSS/SSS tocheck if a UE is in same cell or not. So, determining the best/suitableDL TX beam does not lead to any additional complexity at the UE.

In order to determine the time slot corresponding to best/suitable DL TXbeam, a UE needs to know the mapping between one or more DL TX beams andtime slots in PO. There are two ways of signaling the mapping betweenone or more DL TX beams and time slots in PO.

First, implicit Signaling can be used. The mapping between one or moreDL TX beams and time slots in PO can be implicit. The order in which DLTX beams are used for transmission of NR-PSS/SSS/BCH is same as order inwhich DL TX beams are used for transmission of paging message in PO likeshown in FIG. 8. For example, if best/suitable DL TX beam is TX 5, thena UE monitors only time slot 4 for receiving paging.

Second, explicit Signaling can be used. The mapping between one or moreDL TX beams and time slots in PO can be explicit signaled in systeminformation.

In an alternate embodiment, NR-PSS/SSS/BCH may be transmitted usingmultiple SS blocks. A UE power consumption can be reduced if the UE candetermine the best/suitable SS block (i.e. SS block in which the UE hasreceived the broadcast signals such NR-PSS/SSS/PBCH and RSRP (ReferenceSignal Received Power) of that SS block is best/suitable) and thenmonitors the time slot in PO corresponding to the best/suitable SSblock. Each SS block is identified by SS block ID.

In order to determine the time slot corresponding to best/suitable SSblock, a UE needs to know the mapping between one or more SS blocks andtime slots in PO. There are also two ways of signaling the mappingbetween one or more SS blocks and time slots in PO.

First, implicit Signaling can be used. The mapping between one or moreSS blocks and time slots in PO can be implicit. For example, SS block ID1 is mapped to time slot 1 in PO, SS block ID2 is mapped to time slot 2in PO and so on.

Second, explicit Signaling can be used. The mapping between one or moreSS blocks (SS block IDs) and time slots in PO can be explicit signaledin system information.

In an embodiment, network may indicate whether TX beams used fortransmission of PSS/SSS/PBCH is QCL with those used for transmission ofpaging or not. If not, then a UE monitors all time slots in PO. If yes,then the UE can identify the time slot corresponding to best/suitable DLTX beam or SS block and only monitor that. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple DL TX beams then TX beam with strongest signal quality is thebest DL TX beam. If the signal quality of received signal from a DL TXbeam is above a certain threshold then the signal quality of receivedsignal is a suitable DL TX beam. The threshold can be signaled bynetwork in system information. If a UE is able to receivesynchronization signals and/or broadcast channel successfully frommultiple SS blocks then SS block in which is has received signals withstrongest signal quality is the best SS block. If the signal quality ofreceived signal from a SS block is above a certain threshold then thesignal quality of received signal is a suitable SS block. The thresholdcan be signaled by network in system information.

FIGS. 9A and 9B illustrate embodiments of receiving a paging accordingto various embodiments of the present disclosure.

In a beamformed system, a UE may also perform RX beamforming. If a UEhas several RX beams then a UE has to determine the RX beams forreceiving paging in PO. If a UE has N RX beams and paging is transmittedusing a TX beam only once then a UE wakes up in advance before the PO tomonitor the broadcast signals such as NR-PSS/SSS/BCH, perform RX beamsweeping and determine the best/suitable RX beam (910, 930). A UE thenuses this RX beam to receive paging in PO (920, 940), like shown in FIG.9A and FIG. 9B. Note that this is needed irrespective of whether pagingis FDMed with PSS/SSS/BCH in same time slot or not. A UE has to wakeupN*P ms before the PO (910) where P is the periodicity at which broadcastsignals such as NR-PSS/SSS/BCH are transmitted using full TX beamsweeping as shown in FIG. 9A. Alternately, if paging is FDMed withPSS/SSS/BCH, then the UE has to wakeup (N−1)*P ms before the PO (930) asshown in FIG. 9B.

FIGS. 10A and 10B illustrate embodiments of transmitting broadcastsignals according to various embodiments of the present disclosure.

In the existing system, broadcast signals (such as PSS/SSS/ESS/PBCH/BRS(Beam Reference Signal)) are transmitted periodically. For example,period can be one radio frame where these signals are transmitted insubframe#0 in every radio frame. In order to reduce the early wake uptime, we propose to transmit the broadcast signals (such asPSS/SSS/ESS/PBCH/BRS) more frequently in certain radio frames. In oneembodiment, broadcast signals (such as PSS/SSS/ESS/PBCH/BRS) aretransmitted more frequently in “X” consecutive radio frames (1100)before the paging frame. These “X” radio frames (1100) are referred asspecial radio frames and other radio frames (1110) are referred asnormal radio frames as shown in FIG. 10A.

In an alternate embodiment, “X” consecutive radio frames may include thepaging frame as well, as shown in FIG. 10B. In case of TDD system, these“X” radio frames are “X” consecutive DL radio frames. There can be ULradio frames in between these “X” consecutive DL radio frames. The valueof “X” can be signaled by network in broadcast or dedicated signaling.The value of X can also be pre-defined. The subframes in these “X” radioframes where broadcast signals (such as PSS/SSS/ESS/PBCH/BRS) aretransmitted can also be signaled by network in broadcast or dedicatedsignaling. The subframes in these “X” radio frames where broadcastsignals (such as PSS/SSS/ESS/PBCH/BRS) are transmitted can bepre-defined or signaled by network in broadcast or dedicated signaling.

The additional subframes in these “X” radio frames where broadcastsignals (such as PSS/SSS/ESS/PBCH/BRS) are transmitted may transmitPSS/ESS/SSS using a sequence different than those used in other radioframes. In one embodiment, PBCH transmitted in subframe may includeinformation indicating the subframe # of that subframe. After receivingthe PBCH, this information can be used to determine the start of radioframe as each radio frame has fixed number of subframes.

It is to be noted that above method can also be applied for otherscenarios such as connected mode DRX (in this case instead of defining Xwith respect to paging radio frame, X is specified with respect to firstradio frame of ON duration) or other periodic ON/OFF scenarios.

In one embodiment, the first subframe of the paging frame which containsthese special subframes which contain the extra transmission ofbroadcast signals (such as PSS/SSS/ESS/PBCH/BRS) is indicated in thePDCCH of the first subframe of the paging frame. Alternatively eachsubframe carries the indication of the type of the subframe whether thetype of the subframe is special or normal from the perspective ofcarrying the said one or more broadcast signals such asPSS/SSS/ESS/PBCH/BRS). In another alternative the paging message canindicate the presence of such special subframes in the subsequent pagingoccasion.

FIG. 11 illustrates another embodiment of transmitting broadcast signalsaccording to various embodiments of the present disclosure. In oneembodiment, the broadcast signals (e.g., PSS/SSS/ESS/PBCH/BRS) aretransmitted at shorter periodicity for certain time duration (X, 1110)before the PO (1100). For example, in FIG. 11 normal broadcast period ofPSS/SSS/ESS/PBCH is 80 ms. However before the PO, for example, theperiod is configured as 20 ms. Network may signal duration X (1110) andperiodicity of PSS/SSS/ESS/PBCH during this duration X.

FIG. 12 to 19 illustrates exemplary embodiments of determining pagingoccasion according to the present disclosure. Before determining pagingoccasion, a UE identifies and determines paging frame(s) first. Total 4methods of determining paging frame and paging occasion will bedescribed detail below.

In some embodiments, DRX cycle comprises of one or more paging frames.One PF comprise of one or more Radio Frames. DRX cycle interval ismultiple of paging frame duration. Each PF may contain one or multiplePaging Occasion(s). One PO comprises of one or more paging slots. Pagingslot can be a subframe or TTI or a set of OFDM symbols or slot or minislot. A UE first determines the start of paging frame (PF). PF of the UEstarts at the radio frame (each radio frame is numbered and identifiedby system frame number or SFN) which satisfies the equation 1 below:SFN mod T=(T div N)*(UE_ID mod N)  Equation (1)where, “T” is the duration of DRX cycle in unit of radio frames, “nB” isthe number of paging occasions in duration T, N: min (T/X, nB); N is thenumber of paging frames having at least one paging occasion; X: Numberof radio frames in a PF; In one embodiment X can be 1. X can be signaledin system information. Default value of X can be 1 and used if X is notsignaled, UE_ID: (IMSI or S-TMSI or any other ID) mod N1, and N1 isdetermined based on least significant bits of IMSI or S-TMSI or anyother ID are used as UE ID.

For example, if 10 least significant bits of IMSI or S-TMSI or any otherID are used as UE ID then N1 is 2¹⁰ i.e. 1024, or, UE_ID: ((IMSI orS-TMSI or any other ID)/N2) mod N3; N2 and N3 can be same or different.

For example if bits 10 to bits 19 are to be used as UE ID then N2 and N3are set to 1024. In another example If bits 14 to 24 are to be used asUE ID then N2 is 16384 and N3 is 1024. Parameters T, nB are signaled bynetwork in broadcast or dedicated signaling. X can also be signaled insystem information.

In alternate embodiment, PF of a UE starts at the radio frame (eachradio frame is numbered and identified by system frame number or SFN)which satisfies the equation 2 below:SFN mod T=X*(UE_ID mod N)  Equation (2)where, “T” is the duration of DRX cycle in unit of radio frames, N: T/X;N is the number of paging frames having at least one paging occasion, X:Number of radio frames in a PF.

In one embodiment X can be 1. X can be signaled in system information.Default value of X can be 1 and used if X is not signaled. UE_ID: (IMSIor S-TMSI or any other ID) mod N1; N1 is determined based on how mayleast significant bits of IMSI or S-TMSI or any other ID are used as UEID. For example, if 10 least significant bits of IMSI or S-TMSI or anyother ID are used as UE ID then N1 is 2¹⁰ i.e. 1024.

Or, UE_ID: ((IMSI or S-TMSI or any other ID)/N2) mod N3; N2 and N3 canbe same or different. For example if bits 10 to bits 19 are to be usedas UE ID then N2 and N3 are set to 1024. In another example If bits 14to 24 are to be used as UE ID then N2 is 16384 and N3 is 1024. ParameterT is signaled by network in broadcast or dedicated signaling. X can alsobe signaled in system information

After determining the start of paging frame, paging occasion in pagingframe is identified and/or determined. In first embodiment, the pagingoccasion is determined as following equation 3:PO number=i_s mod(number of POs in a PF)  Equation (3)where, i_s=floor(UE_ID/N) mod Ns; Ns: max (1, nB/(T/X)).

In one embodiment Ns can also be fixed or configured by network. X:Number of radio frames in a PF.

In one embodiment X can be 1. X can be signaled in system information.Number of POs in a PF=Number of paging slots in a PF/(number of pagingslots in each PO). Number of paging slots in each PO=number of TXbeams/number of antenna arrays. It is assumed that t using one antennaarray, one beam can be transmitted in one paging slot.

Each PO in paging frame is sequentially numbered starting from zero.

Number of TX beams and number of antenna arrays are signaled by networkin broadcast or dedicated signaling or number of paging slots in each POis signaled.

An eNB may broadcast paging using all TX beams in PO. Alternately theeNB may transmit using subset of TX beams if the eNB is aware (asdescribed later in the present disclosure TX beams associated with UEsto be paged.

A UE reports the number of the antenna arrays that the UE may use forreception of the paging.

An eNB can use all the TX beams or a subset of the TX beams based on thebest TX beam(s) reported by the UEs corresponding to the PO.

Alternately Number of POs in a PF=Duration of PF/Duration of PO.Duration of PO can be signaled by network in system information orbroadcast or dedicated signaling. Alternately Number of POs in a PF canbe signaled by network in system information or broadcast or dedicatedsignaling.

In second embodiment, the paging occasion is determined as followingequation 4″First paging slot of PO=i_s*i_r  Equation (4)where, i_s=floor(UE_ID/N) mod Ns; Ns: max (1, nB/(T/X)); nB/T may be<=Number of POs in a PF.

In one embodiment Ns can also be fixed or configured by network. X:Number of radio frames in a PF. In one embodiment X can be 1. X can besignaled in system information. i_r=Number of paging slots in eachPO=number of TX beams/number of antenna arrays (Alternate) i_r=Number ofpaging slots in each PO=number of TX beams/(number of antennaarrays*Number of paging channel per paging slot).

Each paging slot in paging frame is sequentially numbered starting fromzero.

A number of TX beams, number of antenna arrays are signaled by networkor number of paging slots in each PO is signaled.

eNBs may broadcast paging using all TX beams in PO. Alternately the eNBmay transmit using subset of TX beams if the eNB is aware (as describedlater in the present disclosure) of TX beams associated with UEs to bepaged.

In third embodiment, the paging occasion is determined as followingequation 5:PO Number=i_s  Equation (5)where, i_s=floor(UE_ID/N) mod Ns; and Ns: max (1, nB/(T/X)).

In one embodiment Ns can also be fixed or configured by network. X:Number of radio frames in a PF.

In one embodiment X can be 1. X can be signaled in system information.Number of POs in a PF=Number of paging slots in a PF/(number of pagingslots in each PO). Number of paging slots in each PO=number of TXbeams/number of antenna arrays. Here we assume that using one antennaarray, one beam can be transmitted in one paging slot.

Alternately, Number of paging slot in each PO==number of TXbeams/(number of antenna arrays*Number of paging channel per pagingslot). Each paging slot can have several time division multiplexedpaging channels.

Alternately Number of POs in a PF=Duration of PF/Duration of PO.Duration of PO can be signaled by network in system information orbroadcast or dedicated signaling. Alternately Number of POs in a PF canbe signaled by network in system information or broadcast or dedicatedsignaling. Each PO in paging frame is sequentially numbered startingfrom zero.

First paging slot of PO=PO#*Number of paging slots in each PO.

eNBs may broadcast paging using all TX beams in PO. Alternately the eNBmay transmit using subset of TX beams if the eNB is aware (as describedlater in the present disclosure) of TX beams associated with UEs to bepaged.

In fourth embodiment, the paging occasion is determined as followingequation 6:PO#=floor(UE_ID/N)mod(number of POs in a PF)  Equation (6)

Number of POs in a PF=Number of paging slots in a PF/(number of pagingslots in each PO).

Number of paging slot in each PO=number of TX beams/number of antennaarrays. Here we assume that using one antenna array, one beam can betransmitted in one paging slot.

Alternately, Number of paging slot in each PO==number of TXbeams/(number of antenna arrays*Number of paging channel per pagingslot). Each paging slot can have several time division multiplexedpaging channels.

Alternately, Number of POs in a PF=Duration of PF/Duration of PO.Duration of PO can be signaled by network in system information orbroadcast or dedicated signaling. Alternately, Number of POs in a PF canbe signaled by network in system information or broadcast or dedicatedsignaling.

Each PO in paging frame is sequentially numbered starting from zero.

Number of TX beams, number of antenna arrays are signaled by network.

First paging slot of PO=PO#*Number of paging slots in each PO

eNBs may broadcast paging using all TX beams in PO. Alternately the eNBsmay transmit using subset of TX beams if an eNB is aware (as describedlater in the present disclosure) of TX beams associated with UEs to bepaged.

In fifth embodiment, the paging occasion is determined as followingequation 7.

i_s to PO number mapping is pre-defined Or, alternately i_s to firstpaging slot of PO is pre-defined. Size of PO is determined as explainedearlier. Equation 7 is given by:i_s=floor(UE_ID/N)mod Ns  Equation (7)where, Ns: max (1, nB/(T/X)); In one embodiment Ns can also be fixed orconfigured by network.

First paging slot of PO=PO#*Number of paging slots in each PO.

Examples of PO numbering are shown in FIG. 12 and FIG. 13. In FIG. 13,one paging slot has several paging channels.

In one embodiment, number of TX beams can be replaced by number of TXbeams*Number of RX beams in the above embodiments.

In some embodiments, DRX cycle comprises of one or more paging frames.One PF comprise of one or more Radio Frames. DRX cycle interval ismultiple of paging frame duration. Each PF contain one Paging Occasion.One PO comprises of one or more paging slots. Paging slot can be asubframe or TTI. A UE first determines the start of paging frame (PF).PF of a UE starts at the radio frame (each radio frame is numbered andidentified by system frame number or SFN) which satisfies the equation1, equation 2 and corresponding definitions above. For betterunderstanding, equation 1 and equation 2 are described again as equation8 and 9. Equation 8 is given by:SFN mod T=(T div N)*(UE_ID mod N)  Equation (8)where, “T” is the duration of DRX cycle in unit of radio frame, “nB” isthe number of paging occasions in duration T, N: min (T/X, nB); N isnumber of paging frames having at least one paging occasion, UE_ID:(IMSI or S-TMSI or any other ID) mod N1; N1 is determined based on leastsignificant bits of IMSI or S-TMSI or any other ID are used as UE ID.

For example, if 10 least significant bits of IMSI or S-TMSI or any otherID are used as UE ID then N1 is 2¹⁰ i.e. 1024.

Or, UE_ID: ((IMSI or S-TMSI or any other ID)/N2) mod N3; N2 and N3 canbe same or different. For example if bits 10 to bits 19 are to be usedas UE ID then N2 and N3 are set to 1024.

In another example If bits 14 to 24 are to be used as UE ID then N2 is16384 and N3 is 1024. Parameters T, nB are signaled by network. X canalso be signaled in system information. Equation 9 is given by:SFN mod T=X*(UE_ID mod N)  Equation (9)where, “T” is the duration of DRX cycle in unit of radio frames. N: T/X;N is the number of paging frames having at least one paging occasion. X:Number of radio frames in a PF; In one embodiment X can be 1. X can besignaled in system information. UE_ID: (IMSI or S-TMSI or any other ID)mod N1; N1 is determined based on least significant bits of IMSI orS-TMSI or any other ID are used as UE ID. For example, if 10 leastsignificant bits of IMSI or S-TMSI or any other ID are used as UE IDthen N1 is 2¹⁰ i.e. 1024.

Or, UE_ID: ((IMSI or S-TMSI or any other ID)/N2) mod N3; N2 and N3 canbe same or different. For example if bits 10 to bits 19 are to be usedas UE ID then N2 and N3 are set to 1024.

In another example If bits 14 to 24 are to be used as UE ID then N2 is16384 and N3 is 1024. Parameter T is signaled by network in broadcast ordedicated signaling. X can also be signaled in system information.

In alternate embodiment, PF of a UE starts at the radio frame (eachradio frame is numbered and identified by system frame number or SFN)which satisfies the equation 10 below:SFN mod T=offset  Equation (10)where “T” is the duration of DRX cycle in unit of radio frame. Offsetcan be zero. Offset can also be signaled.

There can be several paging slots in one radio frame. In one embodiment,the paging slot which constitute the paging occasion can be pre-defined.In another embodiment, the paging slot can be signaled in broadcast ordedicated signaling. In one embodiment the paging slot can be indicateddynamically using PBCH (e.g. MIB or SIB). PBCH transmitted prior (duringa pre-defined time) to paging frame can indicate the paging slots ofpaging occasion or the PBCH transmitted prior to paging can indicatestarting paging slot of paging occasion. The number of paging slots inpaging occasion can be determined as explained in method 1.Subframe/paging slot to TX beam mapping in PO can also be pre-defined orsignaling via RRC or BCH.

In one embodiment all paging slots in paging frame constitute pagingoccasion. An example of PO numbering is shown in FIG. 14 and FIG. 15. InFIG. 15, one paging slot has several paging channels.

In one embodiment, whether TTI for paging message transmission using abeam is one paging slot or multiple paging slots can also be signaled.This can be indicated in BCH or other broadcast signaling. This can besignaled prior to paging frame. Depending on paging load, network canuse one or more paging slots for paging message.

In some embodiments, DRX cycle comprises of one or more paging frames.One PF comprise of one or more radio frames. DRX cycle interval ismultiple of paging frame duration. Each PF may contain one or multiplepaging occasion(s). One paging occasion is by default. Other additionalpaging occasions are indicated if needed as shown in FIG. 16 to FIG. 18.One PO comprises of one or more paging slots. Paging slot can be asubframe or TTI. A UE first determines the start of paging frame (PF).PF of the UE starts at the radio frame (each radio frame is numbered andidentified by system frame number or SFN) which satisfies at least oneof the above-described equations 8, 9 and 10 and correspondingdefinitions.

In alternate embodiment, paging frame can be pre-defined and fixed insystem.

In one embodiment, the paging slot(s) which constitutes the defaultpaging occasion can be pre-defined. It can be the paging slot in whichPSS/SSS/ESS/PBCH is transmitted. In another embodiment, the paging slotcan be signaled in broadcast or dedicated signaling. In one embodimentthe paging slot can be indicated dynamically using PBCH (e.g. MIB orSIB). PBCH transmitted prior (during a pre-defined time) to paging framecan indicate the paging slots of default paging occasion or the PBCHtransmitted prior to paging frame can indicate starting paging slot ofdefault paging occasion. The number of paging slots in paging occasioncan be determined as explained in method 1. Paging slots/paging channelsto TX beam mapping in PO can also be pre-defined or signaling via RRC orBCH.

Information (e.g. location) about additional POs can be indicated in amessage (e.g. paging message) transmitted in default PO if needed. Inone embodiment x LSBs of UE ID can be there in message in transmitted indefault PO to indicate which UEs may monitor which additional PO.Alternately each UE monitors all additional PO (a UE stops monitoringremaining POs if paging is received for the UE in PO). Alternately a UEmonitors a PO if UE ID mod N=PO number, where N is number of additionalPOs or number of additional PO+default PO. Additional POs can be atpre-defined offset with respect to default PO and only indication ofadditional number of POs is needed in a message (e.g. paging message)transmitted in default PO. Alternately explicit location of additionalPOs can be indicated in a message (e.g. paging message) transmitted indefault PO. Alternately a message (e.g. paging message) transmitted inone PO can indicate the presence and location of subsequent PO.Additional POs can be indicated in BCH also. In one embodiment number ofdefault PO can be more than one. One of the default or last PO canindicate additional POs.

In some embodiments, a UE determines the paging frame as follows:

A UE monitors paging in ‘S’ consecutive radio frames starting the radioframe which satisfies the equation 11:SFN mod T=(T div N)*(UE ID mod N); N=min(T/S,nB)  Equation (11)where, “T” is the duration of DRX cycle in unit of radio frame. “nB” isthe number of paging occasions in duration T. N: min(T, nB); UE_ID:(IMSI or S-TMSI or any other ID) mod N1; N1 is determined based on howmay least significant bits of IMSI or S-TMSI or any other ID are used asUE ID. For example, if 10 least significant bits of IMSI or S-TMSI orany other ID are used as UE ID then N1 is 2¹⁰ i.e. 1024.

Or, UE_ID: ((IMSI or S-TMSI or any other ID)/N2) mod N3; N2 and N3 canbe same or different. For example if bits 10 to bits 19 are to be usedas UE ID then N2 and N3 are set to 1024.

In another example, if bits 14 to 24 are to be used as UE ID then N2 is16384 and N3 is 1024.

S=number of radio frames needed for transmitting paging using all Txbeams. S can be one if all TX beams can be transmitted in one radioframe.

Alternately, S=number of radio frames needed for transmitting pagingusing all Tx beams and receiving using all RX beams.

A UE determines the PO in paging frame as follows: In each radio frame,paging slot(s) where paging is transmitted is fixed as shown in FIG. 19.In one embodiment these can be time slot(s) where PSS/SSS/ESS/PBCH/BRSis transmitted. In another embodiment, these can be time slots(s) at anoffset from time slot where PSS/SSS/ESS/PBCH/BRS is transmitted. Inanother embodiment, these can be determined as in the aforementionedembodiments,

FIG. 20 illustrates an embodiment of transmitting paging indicationaccording to various embodiments of the present disclosure. Before thepaging frame a paging indication can be transmitted. The pagingindication is transmitted if paging is there in paging frame. The pagingindication can be broadcasted using beamforming in TTI (2000) as shownin FIG. 20. A TTI (2000) has plurality of paging indication slots. Eachpaging indication slot (PS) has one or more OFDM symbols. The number ofOFDM symbols in each PS can be pre-defined or signaled by network in RRCsignaling or in BCH. Other signals (such as PSS/SSS/ESS/BCH/BRS, etc.)can be transmitted (FDM/CDM) together with paging indication in PS.Paging indication can be transmitted in specific PRBs or all PRBs ineach PS. If paging indication is transmitted in specific PRBs then thesePRBs can be pre-defined or signaled by network in RRC signaling or inBCH. Paging indication message is transmitted using one or more beams ineach PS. Mapping between PS and beam(s) can be pre-defined or signaled.In each PS one or more paging indication channels can be transmitted.Each paging indication channel can be of fixed size (e.g. transmittedover fixed number of PRBs). This can reduce decoding complexity.Alternately paging indication channel can be of variable size.

At least one of the following information might be included in pagingindication.

A) Fixed size bit map. Each bit corresponds to one or more UEs. If sizeof bit map is N, UE ID mod N gives the bit in bitmap corresponding to aUE.

B) Variable size bit map. BCH may indicate the size of bitmap. BCH insubframe X may indicate paging indication info in same subframe or forsubframe at a fixed offset. Each bit corresponds to one or more UEs. Ifsize of bit map is N, UE ID mod N gives the bit in bitmap correspondingto a UE.

FIGS. 21 & 22 illustrates an embodiment of transmitting paging accordingto various embodiments of the present disclosure. And FIG. 21illustrates the signaling flow between a UE and gNB in one embodiment.

Step 1: a UE in idle/inactive state transmits beam information (referredas beam indication signal or message) every paging DRX cycle (S2110).The beam information indicates the suitable or best DL TX beam(s) or SSblock ID(s) of best/suitable SS blocks determined by the UE. Thebest/suitable SS block (i.e. SS block in which the UE has received thebroadcast signals such NR-PSS/SSS/PBCH and RSRP of that SS block isbest/suitable. The DL TX beam is the TX beam of BS/gNB/TRP. The RSRP ofSS block is suitable if the RSRP of SS block is above a threshold wherethe threshold is pre-defined or signaled by network. If a UE hasreceived broadcast signals from multiple SS blocks, then best SS blockis the one with highest RSRP value. A UE may transmit multiple beamindication signals or messages to indicate multiple DL TX beams or SSblock IDs. In an embodiment, one signal or message may indicate multipleDL TX beams or SS block IDs. In an embodiment, the beam indicationsignal or message may indicate best/suitable DL TX beam(s) or SS blockID(s) of best/suitable SS blocks, without any information with respectto a UE ID. That is, UE ID may not be included in the beam indicationsignal or message to reduce overhead of transmitting the beam indicationsignal or message. It is to be noted that this operation is performed byevery UE in idle/inactive state. In an embodiment, network may indicatewhether a UE needs to transmit beam information (referred as beamindication signal or message) in system information. If a UE is campedto a cell, then based on this indication in system information a UEdecides whether the UE needs to transmit beam information (referred asbeam indication signal or message). For example, cell in which paging istransmitted using beamforming may include this indication while othercells in which paging is not transmitted using beamforming may notinclude this indication.

Step 2: BS/gNB/TRP receives beam indication signal or message from UE(s)(S2110). BS/gNB/TRP receives these before each PO. On receiving thesesignals/messages from UEs, BS/gNB/TRP can determine whether there is anyUE in coverage of the BS/gNB/TRP's DL TX beam or not (S2120). Ifsignal/message indicating DL TX beam is received, the BS/gNB/TRPdetermines that at least one UE is in coverage of that DL TX beam. If nosignal/message indicating DL TX beam is received, the BS/gNB/TRPdetermines that there is no UE in coverage of that DL TX beam. Ifsignal/message indicating SS block ID is received, the BS/gNB/TRPdetermines that at least one UE is in coverage of DL TX beam(s)associated with that SS block ID. If no signal/message indicating SSblock ID is received, the BS/gNB/TRP determines that there is no UE incoverage of DL TX beam(s) associated with that SS block ID.

Step 3: Accordingly, when BS/gNB/TRP transmits paging in PO (S2130), theBS/gNB/TRP skips transmission of paging message using a TX beam if thereis no UE in coverage of that TX beam i.e. TX beam which has not beenreported by any UE (S2140) in the beam indication signal. For example,let's say there are 16 TX beam at BS wherein each beam provides coveragein different directions. If the BS has received signal/message(s) fromone or more UE(s) indicating TX beam 1, 5, 8 and 9, then BS transmitspaging using only TX beams 1, 5, 8 and 9 amongst the 16 TX beams. In oneembodiment, if a UE reports TX beam 1 then TX beam 1 and the UE'sneighboring beams can be used by BS to transmit the paging message. Thepaging message includes UE ID (e.g. S-TMSI or IMSI, etc.) of one or moreUEs which are paged. If the UE's UE ID is included, a UE considers thatnetwork has paged the UE and initiates procedure to respond to paging.

FIG. 22 illustrates the transmission of beam indication signal withrespect to PO according to various embodiments of the presentdisclosure. A UE transmits the said beam indication signal/message(2210, 2220) before the PO every DRX cycle. The beam indicationsignal/message can be transmitted at fixed offset from PO. The offsetcan be pre-defined or broadcasted in dedicated signaling

The resources for transmitting the said beam indication signal/messageare signaled to a UE in broadcast or dedicated signaling.

In one embodiment, the resources may comprise of multiple time slots andeach slot is mapped to one or more TX beams (i.e. DL TX beams) or SSblock IDs. A UE transmits a sequence in the time slot corresponding tosuitable or best DL TX beam or SS block. A UE transmits using UL TX beamin having same coverage as the RX beam used to receive the suitable orbest DL TX beam or SS block. The sequence transmitted is fixed in thiscase. The sequence to be transmitted can be configured by the network inbroadcast or dedicated signaling. In an alternate embodiment, multipleslots can be mapped to a TX beam (i.e. DL TX beam) or SS block to allowthe UE to transmit using the UE's multiple TX beams. It is to be notedthat the resources configured for transmitting beam indication signalcan be common for all UEs.

In another embodiment, the resource may comprise of one time slot andsequence to be transmitted is different for different TX beam (i.e. DLTX beam) or SS block. A UE select the sequence corresponding to suitableor DL TX beam or SS block. Mapping between TX beam (i.e. DL TX beam) orSS block and sequence can be fixed or configured by network in broadcastor dedicated signaling. A UE transmits using UL TX beam in having samecoverage as the RX beam used to receive the suitable or best DL TX beamor SS block. In an alternate embodiment, the resource may comprise ofmultiple time slots and sequence to be transmitted is different fordifferent TX beam (i.e. DL TX beam) or SS block. Multiple slots allowthe UE to transmit using the UE's multiple TX beams.

In another embodiment, the resources may comprise of multiple time slotsand each slot is mapped to multiple TX beams. Sequence corresponding tomultiple TX beams mapped to same time slot is different. A UE select thesequence and time slot corresponding to suitable or DL TX beam or SSblock and transmit the sequence in the time slot.

In one embodiment the signal/message can be physical random accesschannel (PRACH) preamble. PRACH resources (time and/or frequency) and/orPRACH preambles corresponding to one or more DL TX beam(s) or SS blockscan be signaled by network in broadcast or dedicated signaling. In orderto indicate a suitable or best DL TX beam or SS block UE transmits MSG 1or PRACH preamble using selected PRACH resource and/or PRACH preamblecorresponding to suitable or best DL TX beam or SS block. It is to benoted that PRACH resource and/or preambles for beam indicationsignal/message can be reserved. In an embodiment, a gNB may transmit RAR(Random Access Response) in response to PRACH preamble transmission andin case RAR is not received, a UE may retransmit the PRACH preamble. Thepower is ramped up during retransmission. In another embodiment, thereis no RAR and a UE may transmit beam indication signal using powerconfigured by network.

In an alternate embodiment, to transmit beam indication signal/message,random access procedure is initiated by a UE. PRACH resources (timeand/or frequency) and/or PRACH preambles corresponding to one or more DLTX beam(s) or SS blocks can be signaled by network in broadcast ordedicated signaling. In order to indicate a suitable or best DL TX beamor SS block UE transmits MSG 1 or PRACH preamble using selected PRACHresource and/or PRACH preamble corresponding to suitable or best DL TXbeam or SS block. Random access procedure (initiated for indicating beamfor paging purpose) is completed after the UE receives the random accessresponse.

In an alternate embodiment, to transmit beam indication signal/message,random access procedure is initiated by a UE. A UE transmits the beamindication signal/message using MSG3 in UL grant received in RAR. MSG3includes the suitable or best DL TX beam ID or SS block ID.

FIG. 23 illustrates another embodiment of transmitting paging accordingto various embodiments of the present disclosure. And FIG. 23illustrates the signaling flow between a UE and gNB in anotherembodiment.

Step 1: a gNB broadcast paging indication using all DL TX beams (S2320).The paging indication may be included in paging message (S2310). In anembodiment, paging indication may include one or more UE group IDs. Ifthere is paging for a UE with UE ID “X” then the UE group ID equals to“X” mod N is included in paging indication. “N” can be predefined orsignaled. In another embodiment, paging indication may include one ormore “N” LSBs of UE IDs. If there is paging for a UE with UE ID “X” then“N” LSBs of UE ID “X” is included in paging indication. In anotherembodiment, paging indication may include a bitmap of length N bits. Ifthere is paging for a UE with UE ID “X,” then ith bit (MSB or LSB) inbitmap is set to one where “i” equals to UE ID mod N. In anotherembodiment, paging indication may include a bitmap of length N bits. Ifthere is paging for a UE with UE ID “X,” then ith bit (MSB or LSB) inbitmap is set to one where “i” equals to (UE ID/N2) mod N, where “N2” isnumber of Paging frames or paging occasions in DRX cycle over which UEsare distributed. In another embodiment, paging indication may include abitmap of length N bits. If there is paging for a UE with UE ID “X,”then ith bit (MSB or LSB) in bitmap is set to one, where “i” is assignedto UE ID “X” by network.

Step 2: a UE transmits beam information (referred as beam indicationsignal or message) only if the UE has received paging indication,example paging indication in paging channel or BCH or SIB or anothermessage (e.g. paging message) indicating that paging is there for UE(s)(S2330, S2340). The beam information indicates the suitable or best DLTX beam(s) or SS block ID(s) of best/suitable SS blocks. Thebest/suitable SS block (i.e. SS block in which the UE has received thebroadcast signals such NR-PSS/SSS/PBCH and RSRP of that SS block isbest/suitable. The RSRP of SS block is suitable if the RSRP of SS blockis above a threshold where the threshold is pre-defined or signaled bynetwork. If a UE has received broadcast signals from multiple SS blocks,then best SS block is the one with RSRP value). A UE may transmitmultiple beam indication signals or messages to indicate multiple DL TXbeams or SS block IDs. In an embodiment, one signal or message mayindicate multiple DL TX beams or SS block IDs.

In another embodiment, a UE transmits the beam indication signal/messageonly if the UE has received paging indication including the UE's UEgroup ID (S2330, S2340) where the UE group ID is equal to the UE ID modN. N can be pre-defined or signaled by network. In another embodiment, aUE transmits the beam indication signal/message only if the UE hasreceived paging indication including the UE's UE group ID (S2330, S2340)where the UE group ID is equal to “N” LSBs (least significant bits) ofthe UE's UE ID. N can be pre-defined or signaled by network. In anotherembodiment, a UE transmits the beam indication signal/message only ifthe UE has received paging indication with ith bit (MSB or LSB) ofpaging indicator bitmap set to one where “i” equals to UE ID mod N.Length of paging indicator bitmap is N bits. In another embodiment, a UEtransmits the beam indication signal/message only if the UE has receivedpaging indication with ith bit (MSB or LSB) of paging indicator bitmapset to one where “i” equals to (UE ID/N2) mod N, where “N2” is number ofPaging frames or paging occasions in DRX cycle over which UEs aredistributed. Length of paging indicator bitmap is N bits.

In another embodiment, a UE transmits the beam indication signal/messageonly if the UE has received paging indication with ith bit (MSB or LSB)of paging indicator bitmap set to one where “i” is assigned to a UE bynetwork. Length of paging indicator bitmap is N bits. Step 3: a gNBreceives beam indication signals/messages from UEs (S2340). On receivingthese signals from UEs, BS/gNB/TRP can determine whether there is any UEin coverage of the BS/gNB/TRP's DL TX beam or not (S2350). Ifsignal/message indicating DL TX beam is received, the BS/gNB/TRPdetermines that at least one UE is in coverage of that DL TX beam. If nosignal/message indicating DL TX beam is received, the BS/gNB/TRPdetermines that there is no UE in coverage of that DL TX beam. Ifsignal/message indicating SS block ID is received, the BS/gNB/TRPdetermines that at least one UE is in coverage of DL TX beam associatedwith that SS block ID. If no signal/message indicating SS block ID isreceived, the BS/gNB/TRP determines that there is no UE in coverage ofDL TX beam(s) associated with that SS block ID.

Step 4: Accordingly, when BS/gNB/TRP transmits paging in PO (S2360), theBS/gNB/TRP skips transmission of paging message using a TX beam if thereis no UE in coverage of that TX beam i.e. TX beam which has not beenreported by any UE (S2370). For example, let's say there are 16 TX beamat BS wherein each beam provides coverage in different directions. Ifthe BS has received signal(s) from one or more UE(s) indicating TX beam1, 5, 8 and 9, then BS transmits paging using only TX beams 1, 5, 8 and9 amongst the 16 TX beams. In one embodiment, if a UE reports TX beam 1then TX beam 1 and the UE's neighboring beams can be used by BS totransmit the paging message. The paging message includes UE ID (e.g.S-TMSI or IMSI, etc) of one or more UEs which are paged. If a UE's UE IDis included, the UE considers that network has paged the UE andinitiates procedure to respond to paging.

In this embodiment, paging indication can be received in PO. A UE thentransmits the said beam indication signal/message after the PO. Aftertransmitting the beam indication signal, paging message can be receivedby a UE in the UE's next PO. Alternately, after transmitting the beamindication signal/message, paging message can be received by the UEwithin a time window. Alternately, after transmitting the beamindication signal/message e.g. in MSG 3, paging message can be receivedby the UE in MSG 4. Alternately, paging indication can be receivedbefore the PO. The location of paging indication can be at an offsetwith respect to PO. After transmitting the beam indication signal UEreceives paging in PO.

The resources for transmitting the said beam indication signal/messageare signaled to a UE in broadcast or dedicated signaling.

In one embodiment, the resources may comprise of multiple time slots andeach slot is mapped to one or more TX beams (i.e. DL TX beam) or SSblock IDs. A UE transmits a sequence in the time slot corresponding tosuitable or best DL TX beam or SS block. A UE transmits using UL TX beamin having same coverage as the RX beam used to receive the suitable orbest DL TX beam or SS block. The sequence transmitted is fixed in thiscase. The sequence to be transmitted can be configured by the network inbroadcast or dedicated signaling. In an alternate embodiment, multipleslots can be mapped to a TX beam (i.e. DL TX beam) or SS block to allowthe UE to transmit using the UE's multiple TX beams. It is to be notedthat the resources configured for transmitting beam indication signalcan be common for all UEs.

In another embodiment, the resource may comprise of one time slot andsequence to be transmitted is different for different TX beam (i.e. DLTX beam) or SS block. A UE select the sequence corresponding to suitableor DL TX beam or SS block. Mapping between TX beam (i.e. DL TX beam) orSS block and sequence can be fixed or configured by network in broadcastor dedicated signaling. A UE transmits using UL TX beam in having samecoverage as the RX beam used to receive the suitable or best DL TX beamor SS block. In an alternate embodiment, the resource may comprise ofmultiple time slots and sequence to be transmitted is different fordifferent TX beam (i.e. DL TX beam) or SS block. Multiple slots allowthe UE to transmit using the UE's multiple TX beams.

In another embodiment, the resources may comprise of multiple time slotsand each slot is mapped to multiple TX beams. Sequence corresponding tomultiple TX beams mapped to same time slot is different. A UE select thesequence and time slot corresponding to suitable or DL TX beam or SSblock and transmit the sequence in the time slot.

In one embodiment the beam indication signal can be PRACH preamble.PRACH resources (time and/or frequency) and/or PRACH preamblescorresponding to one or more DL TX beam(s) or SS blocks can be signaledby network in broadcast or dedicated signaling. In order to indicate asuitable or best DL TX beam or SS block UE transmits MSG 1 or PRACHpreamble using selected PRACH resource and/or PRACH preamblecorresponding to suitable or best DL TX beam or SS block. It is to benoted that PRACH resource and/or preambles for beam indicationsignal/message can be reserved so that on receiving the PRACH preambleBS can identify that received PRACH preamble is for paging purpose. ThePRACH resource and/or preambles can be reserved separately for each UEgroup (or paging indicator/index) or UE groups (or pagingindicator/indexes). In an embodiment, a gNB may transmit RAR in responseto received PRACH preamble and incase RAR is not received UE mayretransmit the PRACH preamble. The power is ramped up duringretransmission. In another embodiment, there is no RAR and UE maytransmit signal using power configured by network.

In an embodiment in which RAR is transmitted on receiving PRACH preambleand BS identifies that received PRACH preamble is for paging purpose,paging information i.e. one or more UE IDs which are paged can beincluded in RAR; alternately paging information i.e. one or more UE IDswhich are paged is not included in RAR and paging message includingpaging information i.e. one or more UE IDs which are paged istransmitted separately after the RAR. If PRACH preamble indicates UEgroup (or paging indicator/index) or UE groups (or pagingindicator/indexes), then on receiving PRACH preamble only one or more UEID which are paged corresponding to that group is included in RAR orpaging message. In case paging information is included in RAR, UL grantmay also be included in RAR. If UE's UE ID is received in RAR (or inother words paging information in RAR includes UE's UE ID), a UEtransmit MSG 3 including connection request or connection resume requestin received UL grant. If multiple UE IDs are included in RAR, UL grantis included for each UE ID. If the UE's UE ID is received in RAR, the UEtransmit MSG 3 including connection request or connection resume requestin UL grant corresponding to the UE's UE ID. In case of non beamformedsystem, after receiving the paging indicator, there is no beamindication signal, but the UE transmits the PRACH preamble. PRACHpreamble does not indicate beam information. The remaining procedure issame as explained above.

In an alternate embodiment, to transmit beam indication signal, randomaccess procedure is initiated by a UE. PRACH resources (time and/orfrequency) and/or PRACH preambles corresponding to one or more DL TXbeam(s) or SS blocks can be signaled by network in broadcast ordedicated signaling. In order to indicate a suitable or best DL TX beamor SS block UE transmits MSG 1 or PRACH preamble using selected PRACHresource and/or PRACH preamble corresponding to suitable or best DL TXbeam or SS block. Random access procedure is completed after the UEreceives the random access response. Random access procedure (initiatedfor indicating beam for paging purpose) is completed after the UEreceives the random access response. The paging information i.e. one ormore UE IDs which are paged can be included in RAR; alternately paginginformation i.e. one or more UE IDs which are paged is not included inRAR and paging message including paging information i.e. one or more UEIDs which are paged is transmitted separately after the RAR. In case ofnon beamformed system, after receiving the paging indicator, there is nobeam indication signal, but the UE transmits the PRACH preamble. PRACHpreamble does not indicate beam information. The remaining procedure issame as explained above.

After sending the beam indication signal (i.e. PRACH preamble), a gNBmay send an acknowledgment indicating beam indication signal isreceived. In case beam indication signal is indicated using MSG1 i.e.PRACH preamble transmission, a gNB sends an RAR indicating reception ofPRACH preamble indicating beam indication signal. In an embodiment RARis successfully received if the RAR corresponds to both PRACH resourceand RAPID used by a UE for PRACH preamble transmission i.e. RAR issuccessfully received if the UE receives a PDCCH addressed to the UE'sRA-RNTI and decoded transport block (MAC PDU) includes RAR carryingRAPID. PDCCH for RAR is addressed to RA-RNTI wherein RA-RNTI is specificto PRACH resource and RAPID is included in RAR MAC PDU. This is the casewhen both PRACH resource and PRACH preamble together identifies aparticular beam indication signal. In another embodiment RAR issuccessfully received if the RAR corresponds to RAPID of PRACH preambletransmitted by the UE i.e. RAR is successfully received if a UE receivesa PDCCH addressed to the UE's RA-RNTI or a reserved RA-RNTI or P-RNTIand decoded transport block (MAC PDU) includes RAR carrying RAPID. Thisis the case when PRACH preamble identifies a particular beam indicationsignal. In another embodiment RAR is successfully received if the RARcorresponds to PRACH resource used by the UE for PRACH preambletransmission i.e. RAR is successfully received if the UE receives aPDCCH addressed to the UE's RA-RNTI. This is the case when PRACHresource identifies a particular beam indication signal. In anotherembodiment of the present disclosure RA-RNTI for receiving RAR for PRACHpreamble transmission indicating beam indication signal can be a commonor reserved RNTI or P-RNTI (predefined or indicated in minimum systeminformation). A UE monitors for PDCCH addressed to this RA-RNTI in RARwindow. If a UE receives RAR scheduled using PDCCH addressed to reserveRA-RNTI, the UE can stop monitoring RAR in RAR window and consider RARreception as successful. Alternately, if a UE receives RAR scheduledusing PDCCH addressed to reserve RA-RNTI and RAR includes RAPID of RACHpreamble transmitted by the UE, the UE can stop monitoring RAR in RARwindow and consider RAR reception as successful. In case of nonbeamformed system, after receiving the paging indicator, there is nobeam indication signal, but the UE transmits the PRACH preamble. PRACHpreamble does not indicate beam information. The remaining procedure issame as explained above.

In an alternate embodiment, to transmit beam indication signal, randomaccess procedure is initiated by a UE. PRACH resources (time and/orfrequency) and/or PRACH preambles corresponding to one or more DL TXbeam(s) or SS blocks can be signaled by network in broadcast ordedicated signaling. In order to indicate a suitable or best DL TX beamor SS block UE transmits MSG 1 or PRACH preamble using selected PRACHresource and/or PRACH preamble corresponding to suitable or best DL TXbeam or SS block. A UE then monitor RAR window for receiving the randomaccess response. In the UL grant received in RAR, the UE transmits MSG3. The MSG3 includes UE ID and paging response indication i.e. a UE istransmitting this as UE has received the paging indicator. Theconnection request or resume request may also be included. On receivingMSG 3 with paging response indication, BS/gNB/TRP checks if there ispage for the UE; if yes, BS/gNB/TRP transmits MSG 4 indicating thatthere is page for the UE; If no, BS/gNB/TRP transmits MSG 4 indicatingthat there is no page for the UE. In an alternate embodiment, onreceiving MSG 3 with a cause value indicating paging indicator response,BS/gNB/TRP checks if there is page for the UE; if yes, BS/gNB/TRPtransmits MSG 4 including RRC connection setup or connection resumemessage; If no, BS/gNB/TRP transmits MSG 4 including RRC connectionreject or resume reject. In case of non beamformed system, afterreceiving the paging indicator, there is no beam indication signal, butthe UE transmits the PRACH preamble. PRACH preamble does not indicatebeam information. The remaining procedure is same as explained above.

In an embodiment, paging message may include the paging indication asdescribed in embodiment 2 or may include the full UE ID of UEs which arepaged. If the paging indication is included in paging message then UEperform the operation as described in embodiment 2. If paging indicationis not included and full UE ID of paged UE is included then UE respondsto page if the UE's UE ID is included in paging message. Paging messagemay include an indication indicating whether the paging message includespaging indication of full UE ID(s).

In addition to procedure described in embodiment 1 and embodiment 2, inthis embodiment, beam indication signal not only indicates the suitableor best DL TX beam or SS block but also UE group ID. In an embodiment, aUE group ID is equal to UE ID mod N. N can be predefined or signaling bynetwork. In another embodiment, UE group ID is equal to “N” LSBs (leastsignificant bits) of UE ID.

On receiving this signal, BS/eNB/TRP can determine whether there is anyUE in coverage of the BS/eNB/TRP's TX beam or not and if a UE is incoverage what is the UE group ID of that UE. Accordingly, whenBS/eNB/TRP transmits paging BS/eNB/TRP skips transmission of pagingmessage using a TX beam if there is no UE in coverage of that TX beamhaving the same UE group ID as the UE group ID of one of the UEs to bepaged. The pair {UE_Idx, DL TX beam ID/SS block ID} is mapped to uniquephysical resource set (time resource, frequency resource, code).

FIGS. 24 to 26 illustrate embodiments of avoiding paging according tovarious embodiments of the present disclosure.

According to an embodiment illustrated in FIG. 24, a cell can be coveredby a plurality of TRPs. And TRPs can be grouped into multiple groupsbased on their physical location in cell coverage. TRP Group ID of eachTRP groups is broadcasted by each TRP in the TRP group. When TRP groupis changed by mobility of UE, the UE sends TRP update message to an eNBof the cell. An eNB maintains mapping of UE Identity (e.g. S-TMSI) andTRP Group. When an eNB receives paging message, paging is done in TRPgroup corresponding to the UE to be paged.

In another embodiment, paging frame in each TRP group can be shifted intime manner by using the TRP group ID, as shown in FIG. 25. For example,a radio frame which meets the equation 12 below is determined to be apaging frame, as the TRP group shifting embodiment applies. Equation 12is given by:SFN mod T=(T div N)*(UE_ID mod N)+(TRP group ID*Offset)  Equation (12)

A UE calculates paging frame using TRP group ID and offset. When an eNBreceives paging message, paging is first done in TRP group 0 and ifpaging response is not received, the eNB pages in TRP group 1 and so on.Also, paging response identification can be done by the eNB usingestablishment cause field in MSG3 or PRACH for paging or some new fieldsin MSG3.

Alternately, DRX cycle offset can be signaled wherein the DRX cycleoffset can be different for different TRP or set of TRPs, as shown inFIG. 26. For example, DRX cycle offset can be determined as theequations 13 or 14 below:SFN mod T=(T div N)*(UE_ID mod N)+(Offset)  Equation (13)(SFN+Offset)mod T=(T div N)*(UE_ID mod N)  Equation (14)

When an eNB receives paging message, paging is first done in TRP(s) withsame DRX cycle offset and if paging response is not received, the eNBpages in using TRP(s) with different offset and so on. Also, pagingresponse identification can be done by the eNB using establishment causefield in MSG3 or PRACH for paging or some new fields in MSG3.

FIG. 27 illustrates an eNB apparatus according to various embodiments ofthe present disclosure.

Referring to FIG. 27, the eNB (2700) includes a transceiver (2710), acontroller (2720) and a memory (2730). The eNB (2700) in FIG. 27 may bereferred to as a gNB or a base station. Alternatively, the transceivermay be implemented as a transmitter and a receiver, and each componentmay be implemented through one or more processors. The transceiver maytransmit paging message and/or synchronization signal to a UE and mayreceive beam indication signal from the UE. The memory may storeinformation from the beam indication signal. The controller isconfigured to identify and/or determine paging frame and pagingoccasion, and controls the transceiver and the memory to process thepaging procedures according to the embodiments of the presentdisclosure. The controller may be implemented through at least oneprocessor.

FIG. 28 illustrates a UE apparatus according to various embodiments ofthe present disclosure.

Referring to FIG. 28, the UE (2800) includes a transceiver (2810), acontroller (2820) and a memory (2830). Alternatively, the transceivermay be implemented as a transmitter and a receiver, and each componentmay be implemented through one or more processors. The transceiver mayreceive paging message and/or synchronization signal from an eNB and maytransmit beam indication signal to the eNB. The memory may storebest/suitable beam information and timing of the paging message and/orsynchronization signal with respect to the beam configuration. Thecontroller is configured to identify and/or determine paging frame andpaging occasion, and controls the transceiver and the memory to processthe paging procedures according to the embodiments of the presentdisclosure. The controller may be implemented through at least oneprocessor.

The above-described embodiments of the present disclosure and theaccompanying drawings have been provided only as specific examples inorder to assist in understanding the present disclosure and do not limitthe scope of the present disclosure. Accordingly, those skilled in theart to which the present disclosure pertains will understand that otherchange examples based on the technical idea of the present disclosuremay be made without departing from the scope of the present disclosure.

Although the present disclosure has been described with an exemplaryembodiment, various changes and modifications may be suggested to oneskilled in the art. It is intended that the present disclosure encompasssuch changes and modifications as fall within the scope of the appendedclaims.

What is claimed is:
 1. A method of a terminal for receiving a pagingmessage in a wireless communication system, the method comprising:receiving, from a base station, first information associated with amonitoring occasion for paging, the first information configuring aduration for the monitoring occasion for paging; identifying a pagingoccasion including at least one monitoring occasion for paging based onthe first information; and receiving, from the base station, a pagingmessage by monitoring a physical downlink control channel (PDCCH) of theat least one monitoring occasion for paging in the paging occasion,wherein each of the at least one monitoring occasion for pagingcorresponds to a different synchronization signal block (SSB).
 2. Themethod of claim 1, wherein the paging message is received in the atleast one monitoring occasion for paging with different transmissionbeams.
 3. The method of claim 1, wherein each of the at least onemonitoring occasion for paging comprises a paging slot.
 4. A terminalfor receiving a paging message in a wireless communication system, theterminal comprising: a transceiver configured to transmit and receivesignals; and at least one processor configured to: receive, from a basestation, first information associated with a monitoring occasion forpaging, the first information configuring a duration for the monitoringoccasion for paging, identify a paging occasion including at least onemonitoring occasion for paging based on the first information, andreceive, from the base station, a paging message by monitoring aphysical downlink control channel (PDCCH) of the at least one monitoringoccasion for paging in the paging occasion, wherein each of the at leastone monitoring occasion for paging corresponds to a differentsynchronization signal block (SSB).
 5. The terminal of claim 4, whereinthe paging message is received in the monitoring occasion for pagingwith different transmission beams.
 6. The terminal of claim 4, whereineach of the at least one monitoring occasion for paging comprises apaging slot.
 7. A method of a base station for transmitting a pagingmessage in a wireless communication system, the method comprising:transmitting, to a terminal, first information associated with amonitoring occasion for paging, the first information configuring aduration for the monitoring occasion for paging; identifying a pagingoccasion including at least one monitoring occasion for paging based onthe first information; and transmitting, to the terminal, a pagingmessage in the paging occasion, wherein a physical downlink controlchannel (PDCCH) of the at least one monitoring occasion for paging inthe paging occasion is monitored to receive the paging message, andwherein each of the at least one monitoring occasion for pagingcorresponds to a different synchronization signal block (SSB).
 8. Themethod of claim 7, wherein the paging message is transmitted in the atleast one monitoring occasion for paging with different transmissionbeams.
 9. The method of claim 7, wherein each of the at least onemonitoring occasion for paging comprises a paging slot.
 10. A basestation for transmitting a paging message in a wireless communicationsystem, the base station comprising: a transceiver configured totransmit and receive signals; and at least one processor configured to:transmit, to a terminal, first information associated with a monitoringoccasion for paging, the first information configuring a duration forthe monitoring occasion for paging, identify a paging occasion includingat least one monitoring occasion for paging based on the firstinformation, and transmit, to the terminal, a paging message in thepaging occasion, wherein a physical downlink control channel (PDCCH) ofthe at least one monitoring occasion for paging in the paging occasionis monitored to receive the paging message, and wherein each of the atleast one monitoring occasion for paging corresponds to a differentsynchronization signal block (SSB).
 11. The base station of claim 10,wherein the paging message is transmitted in the at least one monitoringoccasion for paging with different transmission beams.
 12. The basestation of claim 10, wherein each of the at least one monitoringoccasion for paging comprises a paging slot.
 13. The method of claim 1,wherein a monitoring occasion for paging is frequency divisionmultiplexed with a corresponding SSB, and wherein second informationassociated with a number of a physical resource blocks (PRBs) for themonitoring occasion for paging is received from the base station. 14.The terminal of claim 4, wherein a monitoring occasion for paging isfrequency division multiplexed with a corresponding SSB, and whereinsecond information associated with a number of a physical resourceblocks (PRBs) for the monitoring occasion for paging is received fromthe base station.
 15. The method of claim 7, wherein a monitoringoccasion for paging is frequency division multiplexed with acorresponding SSB, and wherein second information associated with anumber of a physical resource blocks (PRBs) for the monitoring occasionfor paging is transmitted to the terminal.
 16. The base station of claim10, wherein a monitoring occasion for paging is frequency divisionmultiplexed with a corresponding SSB, and wherein second informationassociated with a number of a physical resource blocks (PRBs) for themonitoring occasion for paging is transmitted to the terminal.